Crystallography around the world: Russia

Russia

National Committee for Crystallography web page

Category V

Adhering Body

Russian Academy of Sciences

Secretaries of National Committee

N.I. SOROKINA, Shubnikov Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 119333, Russia

O.A. ALEKSEEVA, Shubnikov Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 119333, Russia 

National Committee

M.V. KOVALCHUK (Chair)
V.L. AKSENOV (Vice-Chair)
V.M. KANEVSKY (Vice-Chair)
S.M. ALDOSHIN
E.V. ANTIPOV
L.A. ASLANOV
A.S. AVILOV
E.V. BOLDYREVA
N.B. BOLOTINA
E.V. CHUPRUNOV
S.N. CHVALUN
G.N. KULIPANOV
V.V. KVARDAKOV
V.V. KVEDER
S.G. KONNIKOV
S.V. KRIVOVICHEV
I.S. LYUBUTIN
I.P. MAKAROVA
V.V. OSIKO
V.O. POPOV
D.YU. PUSHCHAROVSKY
M.K.H. RABADANOV
O.G. SINYASHIN
A.E. VOLOSHIN

This information last updated: 15 Oct 2021

The following crystallographers in Russia are registered in the World Directory of Crystallographers.

(IUCr) crystallographers in Russia

700 entries found

  • Abrosimova, Dr Galina E. Senior Researcher. Institute of Solid State Physics, Russian Academy of Sciences, Chernogolovka, Moscow Region 142432, Russia.
  • Akchurin, Dr Marat Sh. Senior Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Akhmetshina, Miss Tatiana Student. Akademika Pavlova 1, 443011, Samara, Russian Federation.
  • Aksenov, Dr Sergey researcher. X-ray diffraction and synchrotron radiation, Shubnikov Institute of Crystallography RAS, Leninskii prospekt 59, 119333, Moscow, Russian Federation.
  • Aksenov, Dr Viktor Lazarevich Scientific Leader of the Frank Laboratory of Neutron Physics. Frank Laboratory of Neutron Physics, Joint Institute for Nuclear Research, -, 141980, Dubna, Russian Federation.
  • Albov, Dr Dmitry Researcher. Laboratory of Structural Chemistry, Moscow State University, Department of Chemistry, Leninskiye Gory, 119992, Moscow, Russian Federation.
  • Aldoshin, Professor Sergey M. Head of Laboratory; Scientific Director of the Institute of Problems of Chemical Physics. Lab. of Structural Chemistry, Institute of Problems Chemical Physics, Russian Academy of Sciences, Chernogolovka, Moscow Region 142432, Russia.
  • Aleksandrova, Dr Inga P. Head of Laboratory. Laboratory of Radiospectroscopy and Spintronics, L. V. Kirensky Institute of Physics Siberian Branch Russian Academy of Sciences, -, 660036, Krasnoyarsk, Russian Federation.
  • Alekseev, Professor Dr Nikolay V. Senior staff scientist. State Institute of Chemistry and Technology of, Shosse Entusiastov 38, 111121, Moscow, Russian Federation.
  • Alekseeva, Mrs Olga Researcher. Russian Academy of Sciences, Institute of Crystallography, Leninsky pr., 59, 119333, Moscow, Russian Federation.
  • Aleshina, Dr Lioudmila Aleksandrovna Professor. Petrozavodsk State University, Lenin-street, 33, 185910, Petrozavodsk, Russian Federation.
  • Alexandrov, Dr Eugeny Research fellow. Samara Center for Theoretical Materials Science, Samara State Aerospace University, Ac. Pavlov St. 1, 443011, Samara, Russian Federation.
  • Alexeev, Dr Dmitriy Director of Research and Development. street of Admiral Makarova, 125212, Moscow, Russian Federation.
  • Alexeyev, Dr Alexey V. Chemical Engineer. Schlumberger, -, 630090, Novosibirsk, Russian Federation.
  • Aleynikova, Dr Kseniya B. senior lecturer. Voronezh State University, University sq., 1, 394006, Voronezh, Russian Federation.
  • Aliev, Dr Zainutdin G. Senior Researcher. Branch Institute of Chemical Physics, Russian Academy of Sciences in Chernogolovka, Chernogolovka, Moscow Region 142432, Russia.
  • Alshits, Professor Vladimir I. Head of Laboratory. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr, Moscow 117333, Russia.
  • Ananyev, Mr Ivan PhD student. X-RAY STRUCTURAL CENTER, Institute of Organoelement Compounds (INEOS) of RAS, Vavilova Str., 28, 119991, Moscow, Russian Federation.
  • Ancharov, Aleksey Igorevich Scientist. Institute of Solid State Chemistry and Mechanochemistry, Kutateladze st. 18, 630128, Novosibirsk, Russian Federation.
  • Andreev, Mr Pavel PhD-student. Gagarin av., 23, build 3, ap. 401, 603950, Nizhni Novgorod, Russian Federation.
  • Andreeva, Dr Marina A. Leading Researcher. Lomonosov Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Andronikova, Ms Daria PhD student. FerroLab, Ioffe Institute, 26 Politekhnicheskaya, 194021, St. Petersburg, Russian Federation.
  • Anisimova, Dr Vera N. Researcher. Laboratory of Electromechanical Investigations of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Antipin, Mr Alexander Junior Researcher. Shubnikov Institute of Crystallography, Russian Academy of Sciences, Leninsky prospect, 59, 119333, Moscow, Russian Federation.
  • Antipov, Professor Evgeny Head of Laboratory. Chemistry Department, Moscow State University, Leninskie Gory Moscow 119992, Russia.
  • Antonov, Dr Evgenii V. Researcher. Lab. of High-Temperature Crystallization, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Antsishkina, Dr Alla A. Senior Researcher. Lab. of Coordination Compounds Crystal Chemistry, Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 31 Leninsky prosp., Moscow 117907, Russia.
  • Arkhipov, Dmitry E. Researcher. Nesmeyanov Institute of Organoelement Compounds (INEOS, RAS), Vavilov St, 28, 119991, Moscow, Russian Federation.
  • Arkhipov, Dr Sergey researcher. Department of Solid State Chemistry, Novosibirsk State University, Pirogova 1, Novosibirsk, Russia, 630090, Novosibirsk area, 630090, Novosibirsk, Russian Federation.
  • Aronin, Dr Alexander S. Senior Researcher. Institute of Solid State Physics, Russian Academy of Sciences, Chernogolovka, Moscow Region 142432, Russia.
  • Asabina, Dr Elena assistant. Chemical, Nizhniy Novgorod State University, pr. Gagarina 23, 603950, Nizhniy Novgorod, Russian Federation.
  • Asadchikov, Dr Victor E. Head of the sector, Senior Researcher. sector of X-ray reflectometry, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Askhabov, Dr Askhab M. Laboratory Head. Lab. of Experimental Mineralogy, Institute of Geology, Komi Scientific Centre, Ural Department, Russian Academy of Sciences, 54 Pervomaiskaya Str., Syktyvkar 167000, Russia.
  • Aslanov, Professor Leonid Aleksandrovich Head of laboratory. Lab. Structural Chemistry, General Chemistry Faculty, Chemistry Dept., Moscow State University, Moscow 119992, Russia.
  • Astaf'ev, Dr Serge B. Researcher. Laboratory of Crystallophysics, Institute of Crystallography, Russian Academy of Sciences, 59 Leninski pr., Moscow 117333, Russia.
  • Atknin, Mr Ivan student. optics, spectroscopy and physics of nanosystems, Moscow State University, Leninskie gory, 1 - 2, 119991, Moscow, Russian Federation.
  • Atuchin, Dr Victor V. Head of Laboratory. Institute of Semiconductor Physics, Siberian Branch of the Russian Academy of Sciences, acad. Lavrentjeva prospect, 13, 630090, Novosibirsk, Russian Federation.
  • Avdeev, Dr Mikhail researcher. Frank Laboratory of Neutron Physics, Joint Institute for Nuclear Research, Joliot-Curie str. 6, Moscow Reg., 141980, Dubna, Russian Federation.
  • Avdyukhina, Dr Valentina M. Associate Professor. Moscow State University, Lenin-Hills, 1-2, GSP-2, 119992, Moscow, Russian Federation.
  • Avilov, Professor Anatoly S. leading Researcher. Laboratory of Electron Diffraction, Institute of Crystallography, RAS, 59 Leninsky prosp., 117333, Moscow, Russian Federation.
  • Babanov, Professor Dr Yuri Professor. laboratory of micromagnetizm, Institute of Metal Physics, Russian Academy of Sciences, S.Kovalevskaya str.,18, GSP-170, 620219, Ekaterinburg, Russian Federation.
  • Bagryanskaya, Dr Irina Yu. Senior Researcher. Institute of Organic Chemistry Siberian Branch RAS, Lavrentyev Pr. 9, 630090, Novosibirsk, Russian Federation.
  • Baidakova, Dr Marina Scientist. Ioffe Physical Technical Institute, 26 Polytekhnicheskaya, 194021, St Petersburg, Russian Federation.
  • Bakakin, Dr Vladimir V. Chief Researcher. Lab. of Crystal Chemistry, Institute of Inorganic Chemistry Siberian Branch, Russian Academy of Sciences, 3 Lavrentyev prosp., Novosibirsk 630090, Russia.
  • Balaev, Mr Vladislav Postgraduate. Russian Academy of Sciences, A.V.Shubnikov Institute of Crystallography, Leninskii prospekt, 129128, Moscow, Russian Federation.
  • Balagurov, Dr Anatoly M. Division Leader. Frank Lab. of Neutron Physics, Joint Institute for Nuclear Research, Dubna, Moscow Region 141980, Russia.
  • Balyunis, Dr Lyubov E. Senior Researcher. Phase Transition Lab., Institute of Physics, Rostov State University, Pr. Stachki 194, Rostov-on-Don 344090, Russia.
  • Banaru, Dr Alexandru Post Dr.. Chemistry, Moscow State University, Leninskie Hills, 1, build. 3, 119991, Moscow, Russian Federation.
  • Bartashevich, Mrs Ekaterina Professor. Chemistry Department, South Ural State University, Kashirinikh St., 007, Chelyabinsk, Russian Federation.
  • Basalaev, Mr Roman Russia, Petrozavodsk. Faculty of Physical Engineering, Petrozavodsk State University, Komsomolsky street, Karelia, 185026, Petrozavodsk, Russian Federation.
  • Basalaev, Mr Yury M. assistant professor of the chair of theoretical physics. Kemerovo State University, Krasnaya st., 6, 650043, Kemerovo, Russian Federation.
  • Bekker, Professor Tatyana B. Lead Research Scientist. Siberian Branch of Russian Academy of Science, Institute of Geology and Mineralogy, prosp.Koptyuga, 3, -, Novosibirsk, Russian Federation.
  • Belik, Miss Vladislava master degree. Crystallography and Crystal Chemistry, Moscow State University, Leninskiye Gory, 119992, Moscow, Russian Federation.
  • Belokoneva, Professor Dr Elena L. Professor. Department of Crystallography and Crystal Chemistry, Faculty of Geology, Moscow State University, Moscow 119899, Russia.
  • Belov, Dr Alexander Yu. Researcher. Lab. of Crystallophysics, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Belskaya, Ms Ludmila Vladimirovna Lecturer. chemical, Omsk State University, Mira prosp., 55a, 644077, 644077, Omsk, Russian Federation.
  • Belsky, Professor Vitaly K. Chief of Laboratory, Head of Chemistry Dept. in Russian Foundation for basic research. State Scientific Center of Russian Federation, L. Karpov Institute of Physical Chemistry, Karpov Institute of Physical Chemistry, 10 Vorontsovo pole, Moscow 103064, Russia.
  • Belugina, Dr Natalija B. Researcher. Laboratory of Electromechanical Investigations of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Berezhkova, Dr Galina V. Chief Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Beskrovnyi, Dr Anatoly I. Senior Researcher. Frank Lab. of Neutron Physics, Joint Institute for Nuclear Research, Dubna, Moscow Region 141980, Russia.
  • Betsofen, Dr Sergey Ya. Professor. Russian State Technology University - MATI, Dept of Materials Science and Technology, 3 Orshanskaya St, Moscow 121552, Russia.
  • Biryukov, Mr Yaroslav Jr Research Scientist. Institute of Silicate Chemistry of Rus. Acad. of Sc., Saint Petersburg, Makarova emb., 2, 199034, Saint Petersburg, Russian Federation.
  • Bkkar, Mr PHd student. Vyzemski lan, 197022, SaintPetersburg, Russian Federation.
  • Blatov, Professor Vladislav A. Head of Department. General and Inorganic Chemistry DepartmentSamara State Technical UniversityMolodogvardeyskaya St. 244Samara 443100Russia.
  • Blinov, Dr Lev M. Laboratory Head. Lab. of Liquid Crystals, Institute of Crystallography, Russia Academy of Sciences, 59 Leninsky Pr., Moscow 117333, Russia.
  • Bobrikov, Mr Ivan junior resercher. Condensed Matter Department in Frank Laboratory of Neutron Physics, Joint Institute for Nuclear Research, Jouliot Curie, 6, Moscow region, 141980, Dubna, Russian Federation.
  • Bobyr, Mr Nikolay researcher. for Nikolay Bobyr.
  • Bogdashkina, Miss Daria Viktorovna Student. Faculty of Physics, Moscow State Univercity, Leninskie Gory, 119991, Moscow, Russian Federation.
  • Boikova, Miss Anastasiia PhD student. Kurchatov complex of NBICS-technologies, NRC Kurchatov institute, pl. Akademica Kurchatova 1, 123098, Moscow, Russian Federation.
  • Boldyreva, Professor Elena Leading researcher, head of chair of solid state chemistry. Novosibirsk State University ul Pirogova 2 Novosibirsk 90 Russia.
  • Bolotina, Dr Nadezhda B. Leading Researcher. Laboratory of X-ray Structure Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 119333, Russia.
  • Borisov, Professor Stanislav V. Senior Researcher. Crystal chemistry, Institute of Inorganic Chemistry SB RAS, 3 Lavrentiev prosp., 630090, Novosibirsk, Russian Federation.
  • Borovikova, Dr Elena assistent. The department of crystallography and crystall chemistry, Lomonosov's Moscow State University, Geological faculty, Leninskie Gory, GSP-2, A-438, 119992, Moscow, Russian Federation.
  • Borshchevskiy, Dr Valentin senior research staff. MIPT, Ljapidevskogo, 125581, Moscow, Russian Federation.
  • Bruskov, Dr Valery A. Technical Director. Department of Crystallography and Crystallographic Computing, Joint-Stock Company `Ajax', 55 Galernaja Str., St Petersburg 190000, Russia.
  • Bubnova, Professor Dr Rimma S. Researcher. Lab. of Stryctural Chemistry, Institute of Silicate Chemistry, Russian Academy of Sciences, 2 Makarov Nab., St Petersburg 199034, Russia.
  • Bukvetsky, Dr Boris V. Senior Researcher. Institute of Chemistry, Far East Scientific Center, Russian Academy of Sciences, Pr. of the 10th Anniv. of Vladivostok 159, 690022 Vladivostok, Russia.
  • Bulavchenko, Dr Olga A. Researcher. Siberian Division of Academy of Sciences, Boreskov Institute of Catalysis, Akademica Lavrentieva 5, 630090, Novosibirsk, 630090, Novosibirsk, Russian Federation.
  • Bunin, Dr Igor J. Leader Science Collaborator. IPKON RAS, Institute for Complex Development of Mineral Resources of the Russian Academy of Sciences, 4, Kryukovsky Tupik, 111020, Moscow, Russian Federation.
  • Bunina, Dr Olga Senior Researcher. Lab. of Crystal Structure, Institute of Physics, Rostov State University, Pr. Stachky 194, Rostov-on-Don 344104, Russia.
  • Bushuev, Professor Vladimir A. Professor. Solid State Chair, Physics Department, Moscow State University, Vorobjovy Gory, Moscow 117234, Russia.
  • Butashin, Dr Andrey V. Senior Researcher. Lab. of Laser Crystals Physics, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Chekrygina, Miss Deniza Intern Researcher. Vavilova str,5, Russian Federation, 119334, Moscow, Russian Federation.
  • Chernenkov, Dr Yury physicist. Neutron Research Department, Petersburg Nuclear Physics Institute, Gatchina, 188300, St. Petersburg, Russian Federation.
  • Chernyshev, Dr Victor Lecturer. Chemical, South-Russia State Technical University, Prosveschenya, 132, Rostov Region, 346428, Novocherkassk, Russian Federation.
  • Chernyshev, Dr Vladimir Vasilievich Leading researcher. Dept. of Chemistry, Moscow State University, Moscow 119992, Russia.
  • CHETTICHIPALAYAM PRABHAHARAN, Dr SAKTHIDHARAN SENIOR RESEARCHER. Nanotechnology Research Centre, South Ural State University, Prospect Lenin Street, 454080, Chelyabinsk, Russian Federation.
  • Chirgadze, Professor Yuri Nickolaevich Head of Laboratory. Lab. of Protein Structure Analysis, Institute of Protein Research, Russian Academy of Sciences, Pushchino, Moscow Region 142290, Russia.
  • Chuev, Mr Anton postgraduate. Physics, Cherepovets State University, Lunacharsky, Vologda region, 162602, Cherepovets, Russian Federation.
  • Chukhovskii, Professor Felix N. Group leader. Lab. of X-ray Optics and Synchrotron Radiation, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Chumakova, Mrs Alexandra Junior research scientist. Neutron Research Department, Condensed Matter Section, Petersburg Nuclear Physics Institute, Orlova Roscha, Leningrad region, 188300, Gatchina, Russian Federation.
  • Chuprunov, Professor Evgeny V. Head of Department, UNN Rector. Nizhnii Novgorod State University, pr. Gagarina, 23, BLDG 2, 603950, Nizhnii Novgorod, Russian Federation.
  • Chvalun, Professor Dr Sergei N. Head of Laboratory. Institute of Synthetic Polymeric Materials, Profsoyuznaya, 70, Moscow, 117393, Russian Federation.
  • D'yachenko, Dr Oleg G. Senior Researcher. Lomonosov Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Dadinova, Miss Liubov PhD Student. The laboratory of reflectometry and small angle X-ray scattering, A.V.Shubnikov Institute of Crystallography RAS, 59 Leninsky prosp., 119333, Moscow, Russian Federation.
  • Darinskaya, Dr Elena V. Senior Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Darinskii, Dr Alexander N. Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Davydova, Miss Yulia PhD. Department of Nuclear Methods and Magnetic Structures, Shubnikov Institute of Crystallography, Leninskii prospect 59, 119333, Moscow, Russian Federation.
  • Dayniak (Dainyak), Dr Lydia G. (Lidia G.) Researcher. Geological Institute, Russian Academy of Sciences, Pyzhevsky per. 7, 109017, Moscow, Russian Federation.
  • Degtyareva, Dr Valentina F. Senior Researcher. Lab. of X-ray structure Analysis, Institute of Solid State Physics, Chernogolovka, Moscow Region 142432, Russia.
  • Derkacheva, Ms Elena Sergeevna postgraduate student. Department of Crystallography, Institute of Silicate Chemistry RAS, -, Russian Federation, -, St.Petersburg, Russian Federation.
  • Dimitrova, Dr Olga V. Senior Researcher. Department of Crystallography and Crystal Chemistry, Faculty of Geology, Moscow State University, Moscow 119899, Russia.
  • Dmitricheva, Elena Vyacheslavovna Researcher. Laboratory of X-ray and synchrotron radiation methods, Shubnikov Institute of Crystallography of Russian Academy of Sciences, Leninsky prospekt, 59, 119333, Moscow, Russian Federation.
  • Dmitrienko, Dr Vladimir E. Main Researcher. Theoretical Department, A.V.Shubnikov Institute of Crystallography RAS, 59 Leninsky pr., Moscow 119333, Russia.
  • Dmitrieva, Dr Tatiana V. Senior Researcher. Lab. of Resonance Methods, Institute of Crystallography, Russian Academy of Science, 59 Leninsky prosp., Moscow 117321, Russia.
  • Dobretsova, Elena student. Geological Faculty of Lomonosov's Moscow State University, Leninskie Gory, 1, 119991, Moscow, Russian Federation.
  • Dobrynin, Dr Alexey researcher. X-Ray Analysis, A. E. Arbuzov Institute of Organic and Physical Chemistry, Kazan Scientific Center of Russian Academy of Sciences, Arbuzov 8, 420088, Kazan, Russian Federation.
  • Dolgushin, Mr Fyodor M. Junior Researcher. X-ray Structural Center of the Russian Academy of Sciences, Institute of Organoelement Compounds, Russian Academy of Sciences, 28 Vavilov St., Moscow 117813, Russia.
  • Domoroshchina, Dr Elena Oxide crystals growth and characterization. Physics and chemistry of solids, Lomonosov state academy of fine chemical technology, 86, Varnadsky pr., Russia, 119571, Moscow, Russian Federation.
  • Doynikova, Dr Olga A. Senior Researcher. Laboratory of Electron Microscopy and Electronography, Institute of Ore Deposits, Petrology, Mineralogy and Geochemistry, Russian Academy of Sciences (IGEM RAS), Staromonetny 35, Moscow 109017, Russia.
  • Drebushchak, Dr Tatiana Senior Researcher. dtn0409@gmail.com.
  • Drits, Professor Victor A. Laboratory Head. Lab. for Investigation of Rock-Forming Minerals by Physical Methods, Geological Institute, Russian Academy of Sciences, Pyzhevsky per. 7, Moscow 109017, Russia.
  • Drozdov, Dr Yurii N. Leading research associate. Heterostructure Technology, Institute for Physics of Microstructures RAS, Academicheskaya Str., 7, Nizhny Novgorod, 603950, Afonino, Russian Federation.
  • Druzhbin, Dmitry Student. Novosibirsk State University, Pirogova 2, 630090, Novosibirsk, Russian Federation.
  • Dubinin, Mr Peter eldest scientific worker. Laboratory of XRPD analysis and research, Siberian federal university, Svobodni avenue, 95, 660025, Krasnoyarsk, Russian Federation.
  • Dudka, Dr Alexander P. Senior Researcher. Laboratory of X-ray Structure Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Dyachenko, Professor Dr Oleg deputy director. Russian Foundation for basic research, Leninskii av., 32a, 119991, Moscow, Russian Federation.
  • Dyakova, Dr Yulia Scientific Secretary. Crystallography and Photonics, Shubnikov Institute of Crystallography of Federal Scientific Research Centre (Russian Academy of Sciences), Leninsky prospekt 59, 119333, Moscow, Russian Federation.
  • Dyuzheva, Dr Tatyana Ivanovna Senior Research Scientist. Lab. of Monocrystals, Vereschagin Institute for High-Pressure Physics RAS, -, 142190, Troitsk, Moscow Region, Russian Federation.
  • Dzyabchenko, Dr Alexander Valentinovich Head of Sector. Karpov Institute of Physical Chemistry, 10 Vorontsovo pole, Moscow 103064, Russia.
  • Efremov, Dr Valery A. Researcher. 3-63 Maliy Kupavinsky Projezd, Moscow 105568, Russia.
  • Emelyanov, Dr Andrey National Research Centre. Nano-, bio-, info-, cogno-, socio- centre, National Research Centre, 1 Sq. Akademika Kurchatova, 123182, Moscow, Russian Federation.
  • Eremin, Mr Nickolai N. Researcher. Vernadsky Institute of Geochemistry and Analytical Chemistry, Russian Academy of Sciences, 19 Kosygin St., Moscow 117975, Russia.
  • Eremkin, Dr Vladimir V. Senior Researcher. Institute of Physics, Rostov State University, Pr. Stachki 194, Rostov-on-Don 344090, Russia.
  • Evlanova, Dr Nina Fedorovna Researcher. Physical Department, Moscow State University, Moscow 119899, Russia.
  • Evstigneeva, Dr Tatiana Leader Researcher, deputy-head of the Laboratory of Mineralogy. Laboratory of Mineralogy, Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry of Russian Academy of Sciences (IGEM RAS), Staromonetny 35, 119017, Moscow, Russian Federation.
  • Fayzullin, Dr Robert R. senior researcher. Laboratory of Diffraction Research Methods, Arbuzov Institute of Organic and Physical Chemistry, FRC Kazan Scientific Center, Russian Academy of Sciences, 8 Arbuzov Street, 420088, Kazan, Russian Federation.
  • Fedorov, Professor Dr Pavel P. Head of Lab.. Prokhorov General Physics Institute RAS, Russian Academy of Sciences, Vavilova, 38, Moscow 119991, Russia.
  • Fedorov, Dr Vladimir A. Researcher. Lab. of Acoustooptics of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Fetisov, Dr Gennady Vladimirovich Chief researcher. Lab. Structural Chemistry, Chemistry Dept., Moscow State University, Moscow 119899, Russia.
  • Filatov, Dr Evgeny researcher. laboratory of chemistry of rare platinum metals, Nikolaev institute of inorganic chemistry SB RAS, Lavrentiev ave. 3, 630090, Novosibirsk, Russian Federation.
  • Filatov, Professor Dr Stanislav K. Crystallography, Saint Petersburg State University, University Emb., 7/9, 199034, Saint Petersburg, Russian Federation.
  • Filipenko, Olga S. Senior Researcher. Institute of Chemical Physics, Russian Academy of Sciences in Chernogolovka, Chernogolovka, Moscow Region 142432, Russia.
  • Flerov, Dr Igor N. Senior Researcher. Lab. of Crystal Physics, Institute of Physics, Siberian Dept., Russian Academy of Sciences, Krasnoyarsk 660036, Russia.
  • Fofanov, Professor Dr Anatoly Dmitrievitch Professor. Solid State Physics, Institute of Physics and Technology, Petrozavodsk State University, Lenin-street, 33, 185910, Petrozavodsk, Russian Federation.
  • Franke, Dr Valeria D. Senior Researcher. Crystal Genesis Lab., St Petersburg University, University Emb. 7/9, St Petersburg 199034, Russia.
  • Frank-Kamenetskaya, Professor Olga Professor. Olga V. Frank-Kamenetskaya, Crystallography dep., Saint Petersburg St.Univrsity, 199034 Saint Petersburg, Russia.
  • Frolov, Mr Kirill Researcher. Lab. of Resonance Methods, Institute of Crystallography, Russian Academy of Science, 59 Leninsky prosp., 117333, Moscow, Russian Federation.
  • Furmanova, Professor Nina G. Chief Researcher. Laboratory of X-ray Structure Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Fykin, Dr Leonid E. Senior Researcher. Lab. for Structural Studies, Karpov Institute of Physical Chemistry, Obninsk Branch, Obninsk, Kaluga Region 249020, Russia.
  • Galstyan, Dr Victor G. Group Leader. Lab. of Crystallization from Vapor Phase, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Gatilov, Dr Yuri V. Leading Researcher. Institute of Organic Chemistry Siberian Branch RAS, Lavrentyev Pr. 9, 630090, Novosibirsk, Russian Federation.
  • Gavrilova, Professor Dr Nadezhda Dmitrievna Professor. Physics Department, Laboratory of Broadband Dielectric Spectroscopy, Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Gavrilyachenko, Professor Victor G. Professor. Nanotechnology Department, Southern Federal University, Zorge St 5 (a. 036), 344090, Rostov-on-Don, Russian Federation.
  • Gayvoronskaya, Miss Kseniya A. student. The X-ray analysis laboratory, Institute of Chemistry, Far Eastern Branch, Russian Academy of Sciences, 159, Prosp. 100-letya Vladivostoka, Primorsky Krai, 690022, Vladivostok, Russian Federation.
  • Gazhulina, Ms Anastasia Lecturer. N.I. Lobachevsky State University of Nizhni Novgorod (NNSU), Gagarin Avenue, 23, building 3, 603950, Nizhni Novgorod, Russian Federation.
  • Geguzina, Dr Galina A. Senior Researcher. Institute of Physics, Southern Federal University, 194 Stachki Ave., Russia, 344090, Rostov-on-Don, Russian Federation.
  • Gerasimenko, Dr Andrey Head of the X-Ray Diffraction Studies Laboratory. X-Ray Diffraction Studies Laboratory, Institute of Chemistry of the Far East Branch of the Russian Academy of Sciences, 159 Pr-t 100-letiya Vladivostoka, 690022, Vladivostok, Russian Federation.
  • Gerasimov, Mr Evgeniy Russia, Novosibirsk. Boreskov Institute of Catalysis SB RAS, pr. Lavrentieva 5, Novosibirsk, Russian Federation.
  • Gerasimov, Dr Victor I. Associate Professor. Mordovian State U., 68a Bolshevitskaya St., Saransk 430000, Russia.
  • Geraskin, Dr Valery V. Associate Professor, retired?. Department of Crystallography, Institute of Steel and Alloys, 4 Leninsky prosp.Russia, 117936, Moscow, Russian Federation.
  • Givargizov, Professor Eugene Invievitch Head of Laboratory. Lab. of Crystallization from Vapor Phase, Institute of Crystallography, RAS, 59 Leninsky pr., 119333, Moscow, Russian Federation.
  • Glazov, Professor Dr Alexei Ivanovich Professor. Chair of Mineralogy Crystallography and Petrography, Geological Research Faculty, St Petersburg Mining Institute, 2, 21st Liniya, 199026, St Petersburg, Russian Federation.
  • Glukhov, Dr Ivan V. Research assistant. X-ray diffraction Centre, A.N. Nesmeyanov Institute of Organoelement Compounds RAS, Vavilova str., 119991, Moscow, Russian Federation.
  • Gol`tsev, Andrey student. 22 Parts`ezda, 443066, Samara, Russian Federation.
  • Golovanov, Dr Denis G. Researcher. A. N. Nesmeyanov Institute of Organoelement Compounds (RAS), Vavilov 28, 119991, Moscow, Russian Federation.
  • Goloveshkin, Alexander Russia. X-ray structural centre, A. N. Nesmeyanov Institute of Organoelement Compounds of Russian Academy of Sciences (INEOS RAS), Vavilova St. 28, 119991, Moscow, Russian Federation.
  • Golovko, Dr Yurii I. Senior Researcher. Lab. of Crystal Physics, Institute of Physics, Rostov State University, Pr. Stachky 194, Rostov-on-Don 344104, Russia.
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  • Ivanova, Dr Anna Senior scientist. Institute of Crystallography, Russian Academy of Science, Leninskii prospekt, 59, Russia, 119333, Moscow, Russian Federation.
  • Ivanova, Ms Elena S. Junior Researcher. Laboratory of Electromechanical Investigations of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
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  • Kuzmin, Dr Ivan I. Senior Researcher. Dept. of Radiative Physics, Obninsk Branch, Karpov Institute of Physical Chemistry, Obninsk, Kaluga Region 249020, Russia.
  • Kuzmina, Dr Ludmila G. Chief Researcher. Laboratory of Crystal Chemistry of Coordinational Compounds, Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 31 Leninsky prosp., Moscow, Russia.
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  • Kuznetsova, Miss Natalia Chemical, Nizhny Novgorod State University, Gagarin av., 23, 603950, Nizhny Novgorod, Russian Federation.
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  • Lazarenko, Mr Vladimir PhD student. NRC, Akademica Kurchatova pl, 123098, Moscow, Russian Federation.
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  • Leonenko, Egor Viktorovich Department of Crystallography and Crystal Chemistry, Lomonosov Moscow State University, Moscow, Academic Kapitsa street, 6/95, 117647, Moscow, Russian Federation.
  • Lepeshov, Dr Gregory Searcher. Institute of Crystallography RAS, Leninskii pr., 59, 119333, Moscow, Russian Federation.
  • Levin, Dr Alexandr A. Researcher. MaMFIS Laboratory, Shatelen Street 26A, 194021, St. Petersburg, Russian Federation.
  • Levtsova, Mrs Anastasia postgraduate student. Russian Academy of Sciences, Frumkin Institute of Physical Chemistry and Electrochemistry, Leninskii pr. 31, block 4, 119991, Moscow, Russian Federation.
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  • Likhachev, Mr Igor Moscow, Russia. NRC Kurchatov Institute, 1, Akademika Kurchatova pl., Moscow, 123182, Russia, 123182, Moscow, Russian Federation.
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  • Litvinov, Professor Igor Head of the Laboratory. Institute of Organic and Physical Chemistry, Kazan Scientific Center, Russian Academy of Sciences, Arbuzov Str. 8, Kazan 420088, Russia.
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  • Losev, Mr Evgeniy PhD student. Group of Reactivity of Solids, Institute of solid State Chemistry and Mechanochemistry SB RAS, Kutateladze 18 str., 630128, Novosibirsk, Russian Federation.
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  • Maevsky, Mr Andrew Vishnevskogo 10-50, Moscow, Russian Federation.
  • Magarill, Dr Svetlana A. Senior Researcher. Laboratory of Crystal Chemistry, Institute of Inorganic Chemistry Siberian Branch, Russian Academy of Sciences, 3 Ak. Lavrentiev prosp., Novosibirsk 630090, Russia.
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  • Maleev, Professor Dr Andrey V. Head of the Department of General and Theoretical Physics. Department of Physics, Vladimir State University, Department of Physics, 11 Stroiteley pr., Vladimir 600024, Russia.
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  • Maltsev, Dr Victor Viktorovich Senior Reseacher. Crystallography and Crystal Chemistry, Geological Faculty, Moscow State University, Leninskye Gory, GSP-2, 119992, Moscow, Russian Federation.
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  • Melnikova, Dr Nina Associated Professor. Low Temperature Physics, Ural State University, 51 Lenina avenue, 620083, Ekaterinburg, Russian Federation.
  • Melnikova, Dr Svetlana V. Researcher. Laboratory of Crystal Physics, Institute of Physics, Siberian Dept., Russian Academy of Sciences, Krasnoyarsk 660036, Russia.
  • Melnikova, Miss Tatyana Researcher. Laboratory of X-Ray Study, Department of Solid State Physics and Chemistry, Lomonosov State Academy of Fine Chemical Technology, Vernadsky prospect, 119571, Moscow, Russian Federation.
  • Mikhailov, Dr Albert M. Chief researcher. Laboratory of Biocrystal Structure, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Mikhailova, Miss Alexandra Baikov Institute of Metallurgy and Materials of RAS, Leninskii pr. 49, 119991, Moscow, Russian Federation.
  • Mikhaylina, Alisa Student. Institute of Protein Research, Institutskaya 4, 142290, Puschino, Russian Federation.
  • Mill', Dr Boris V. Senior Researcher. Physics Department, Moscow State University, Moscow 119899, Russia.
  • Minacheva, Dr Lidiya Kh. Senior Researcher. Laboratory of Coordination Compounds Crystal Chemistry, Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 31 Leninsky prosp., Moscow 117907, Russia.
  • Minkov, Mr Vasily Novosibirsk State University. Solid State Chemistry, Novosibirsk State University, Pirogov str., 2, 630090, Novosibirsk, Russian Federation.
  • Minyukov, Dr Sergey M. Senior Researcher. Laboratory of Electromechanical Investigations of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Mironov, Mr Andrei V. Researcher. Moscow State University, Laboratory of Inorganic Crystallochemistry, Inorganic Chemistry Department, Moscow State University, Leninskie Gory Moscow 119899, Russia.
  • Mokhov, Dr Andrey V. Senior Researcher. Laboratory of Electron Microscopy and Electronography, Institute of Geology of Ore Deposits, Petrology, Mineralogy and Geochemistry, Russian Academy of Sciences (IGEM RAS), Staromonetny 35, 109017 Moscow, Russia.
  • Molchanov, Dr Vladimir N. Senior Researcher. Laboratory of X-ray Structure Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Morozov, Dr Vladimir P. associate professor. Kazan State University, Kremlevskay St., 18, 420008, Kazan, Russian Federation.
  • Mukhamedzhanov, Dr Enver Kh. Leading Researcher. Kurchatov Institute National Research Centre, 1, Akademika Kurchatova pl., 123182, Moscow, Russian Federation.
  • Muntyanu, Mr Roman F. student. Moscow Institute of Steel and Alloys, State Technological University, Profsoyznaya st.,83,2,1409/ 117279, Moscow, Russian Federation.
  • Murashova, Dr Elena V. Researcher. Lab. of Rare Elements Chemistry and Inorganic Polymers, Kurnakov Institute of General and Inorganic Chemistry, Russian Academy of Sciences, 31 Leninsky prosp., Moscow, Russia.
  • Nalbandyan, Dr Vladimir Associate Professor. Vladimir Nalbandyan, Chemistry Faculty, Southern Federal University, 7 ul. Zorge, Rostov-na-Donu, 344090 RUSSIA.
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  • Naumov, Dr Dmitry Yurievich Senior Researcher. Crystal Chemistry, Nikolaev Institute of Inorganic Chemistry SB RAS, Academician Lavrentiev Avenue 3, 630090, Novosibirsk, Russian Federation.
  • Naumova, Dr Inessa I. Senior Research Associate. Moscow State University, Moscow 119899, Russia.
  • Nekrasov, Dr Yuri V. Senior researcher. Laboratory of Biocrystal Structure, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
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  • Nikolaeva, Ms Alena PhD student. Department of structural biochemistry of proteins, Bach Institute of Biochemistry RAS, Leninsky prospekt, Russian Federation, 119071, Moscow, Russian Federation.
  • Nikonov, Dr Stanislav Vladimirovich Group Leader. Group of Structure Investigations of Ribosomal Proteins, Institute of Protein Research, Russian Academy of Sciences, Institutskaya 4, Pushchino Region, 142290, Moscow, Russian Federation.
  • Nikulin, Dr Alexey senior staff scientist. The group for structural studies of ribosomal proteins, Institute of Protein Research, Institutskaya 4, Moscow region, 142290, Pushchino, Russian Federation.
  • Nizamutdinov, Dr Nazim M. Associate Professor. Dept. of Geology, Kazan State University, 18 Lenin Str., Kazan 420008, Russia.
  • Nosik, Dr Valery Head of the sector (neutron diffraction). Neutron diffraction sector, Institute of Crystallography RAS, Leninsky pr.59, Moscow 117333, Russia.
  • Novakova, Dr Alla A. Chief Lecturer. Solid State Chair, Physics Department, Moscow State University, Vorobjovy Gory, Moscow 117234, Russia.
  • Novikova, Dr Natalia N. Researcher. Lab. of X-ray Optics and Synchrotron Radiation, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
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  • Oganov, Professor Artem R. Professor and Head of Laboratory. Material Discovery Laboratory, Skolkovo Institute of Science and Technology, Boulevard 30, bld. 1, -, 121205, Moscow, Russian Federation.
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  • Osipov, Mr Evgeny research scientist. Laboratory of Enzyme Engineering, A.N. Bach Institute of Biochemistry, Leninsky pr. 33, Moscow, Russia 119071.
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  • Ovchinnikov, Dr Yurii E. Senior Lecturer. Physics Department, Novosibirsk State Pedagogical Institute, 28 Vilyuiskaya St., Novosibirsk 630126, Russia.
  • Ovchinnikova, Dr Elena N. Senior Researcher. Physics Department, Lomonosov Moscow State University, Leninskie Gory, 1, Moscow 119992, Russia.
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  • Ovsyannikov, Dr Alexander S. senior researcher. Arbuzov Institute of Organic and physical chemistry, Arbuzova 8, 420088, Kazan, Russian Federation.
  • Ozerin, Dr Alexander Nikiforovich Vice Director. Polymer Materials Structure, Enikolopov Institute of Synthetic Polymer Materials (ISPM RAS), Profsoyuznaya ul. 70, 117393, Moscow, Russian Federation.
  • Panchenko, Mr Anton PhD Student. Laboratory of Crystal Chemistry, Nikolaev Institute of Inorganic Chemistry SB RAS, Acad. Lavrentiev Ave., 3, 630090, Novosibirsk, Russian Federation.
  • Panich, Professor Anatoly E. Faculty Dean. Southern Federal University, 105/42 Bolshaya Sadovaya Str., 344006, Rostov-on-Don, Russian Federation.
  • Pankova, Ms Arina Ph.D student. Inorganic Chemistry, Samara State University, Ac. Pavlov St. 1, 443011, Samara, Russian Federation.
  • Pankova, Miss Yulia Student. Korablestroiteley St., 20-1, 199226, Saint-Petersburg, Russian Federation.
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  • Pashaev, Dr Elkhan M. Leading Researcher. Institute of Crystallography RAS, Leninskii pr., 59, 119333, Moscow, Russian Federation.
  • Pavlov, Dr Sergey Vasilyevich Researcher. Physics, Moscow State University, Russia, 119899, Moscow, Russian Federation.
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  • Pervukhina, Dr Natalie V. Senior Researcher. Laboratory of Crystal Chemistry, Institute of Inorganic Chemistry Siberian Branch, Russian Academy of Sciences, 3 Ak. Lavrentiev prosp., Novosibirsk 630090, Russia.
  • Pet'kov, Dr Vladimir I. associate professor. Chemistry, National Research Lobachevsky State University of Nizhny Novgorod, Pr. Gagarina 23, 603950, Nizhniy Novgorod, Russian Federation.
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  • Petrzhik, Dr Ekaterina A. Researcher. Laboratory of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Petukhov, Professor Boris V. Chief researcher. Lab. of Crystallophysics, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 119333, Russia.
  • Pikin, Professor Sergey A. Deputy Director. Laboratory of Crystallophysics, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Pirogov, Dr Alexander seniour scientist. Dr. A. N. Pirogov, Institute of Metal Physics, S. Kovalevskaya str. 18, Ekaterinburg 620990, Russia.
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  • Podberezskaya, Dr Nina Vasilievna Crystal chemistry, Institute of Inorganic Chemistry SB RAS, Academician Lavrentiev Avenue 3, 630090, Novosibirsk, Russian Federation.
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  • Pushilin, Mikhail Aleksandrovich engineer. X-Ray Diffraction Studies Laboratory, Institute of Chemistry of the Far East Branch of the Russian Academy of Sciences, 159 Pr-t 100-letiya Vladivostoka, 690022, Vladivostok, Russian Federation.
  • Pushkin, Dr Denis Senior lecturer. Department of Chemistry, Samara State University, Ac. Pavlov str., 1, 443011, Samara, Russian Federation.
  • Putilin, Dr Sergei N. Leading Researcher. Lomonosov Moscow State University, Laboratory of Inorganic Crystallochemistry, Leninskie Gory 1, Moscow 119992, Russia.
  • Pyankova, Ms Lyubov Russia. St-Petersburg State Universary, Yniversitetskay st. 7/9, St-Petersburg, Russian Federation.
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  • Rakova, Dr Elena V. Senior Researcher. Laboratory of Electron Diffraction, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Rashchenko, Dr Sergey Vladimirovich Research scientist. Sobolev Institute of Geology and Mineralogy, 3 Koptyug Avenue, 630090, Novosibirsk, Russian Federation.
  • Rashkovich, Professor Leonid N. Professor. Chair of Polymer and Crystal Physics, Physics Department, Moscow State University, Moscow 119992, Russia.
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  • Rau, Professor Valery G. Professor. Physics, Vladimir State University, Gorkogo St., 87, 600000, Vladimir, Russian Federation.
  • Razumnaya, Ms Anna laboratory assistant. Physics, Southern Federal University, 5, Zorge str., 344090, Rostov-on-Don, Russian Federation.
  • Rebrov, Dr Alexander V. Senior Researcher. Laboratory of Polymer Structure, Karpov Institute of Physical Chemistry, 10 Obukha St., Moscow 103064, Russia.
  • Repnikova, Dr Ekaterina A. Assist. professor, retired. Petrozavodsk State University, Lenin-street, 33, 185910, Petrozavodsk, Russian Federation.
  • Revkevich, Dr Galina P. Senior Researcher. Physics Department, Moscow State University, Vorobjovy Gory, Moscow 119234, Russia.
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  • Rozova, Dr Marina G. Associate Professor. Lomonosov Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Rudskaya, Ms Angela Associate Professor. Physics, Southern federal university, 5, Zorge str., 344090, Rostov-on-Don, Russian Federation.
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  • Rusakov, Mr Alexey student. St. Petersburg state University, Rubinsteina 6 17, St. Petersburg, 191025, St. Petersburg, Russian Federation.
  • Rusakov, Mr Anton postgraduate. Laboratory of Physics of single crystals, A.P. Vinogradov Institute of Geochemistry Siberian Branch of the Russian Academy of Sciences, 1 a Favorsky str., 664033, Irkutsk, Russian Federation.
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  • Rybalova, Ms Tatjana V. Researcher. Institute of Organic Chemistry Siberian Branch RAS, Lavrentyev Pr. 9, 630090, Novosibirsk, Russian Federation.
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  • Rychkov, Mr Denis Novosibirsk State University. REC-008, Novosibirsk State University, Pirogova, 2, 630090, Novosibirsk, Russian Federation.
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  • Safonova, Dr Tatiana N. Researcher. Laboratory of Biocrystal Structure, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
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  • Samotin, Dr Nikolay D. Senior Researcher. Lab. of Electron Microscopy, Institute of Ore Deposits, Petrology, Mineralogy and Geochemistry, Russian Academy of Sciences (IGEM RAS), Staromonetny 35, Moscow 109017, Russia.
  • Samygina, Dr Valeria senior scientist. Institute of Crystallography, Leninsky pr, 59, 119333, Moscow, Russian Federation.
  • Sapozhnikov, Dr Anatoly N. Senior Researcher. Institute of Geochemistry, Siberian Branch, Russian Academy of Sciences, 1a Favorsky St., Irkutsk 664033, Russia.
  • Savchenkov, Dr Anton Vladimirovich Associate Professor. Inorganic Chemistry, Samara National Research University, 1 Akademika Pavlova street, 443011, Samara, Russian Federation.
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  • Seredin, Professor Boris Professor. Platov South-Russian State Polytechnic University, St. Enlightenment, 132, 346428, Novocherkassk, Russian Federation.
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  • SHCHERBACHEV, Dr Kirill Physicist. Semiconductor Materials Science, National University of Science and Technology, Leninskiy ave., 4, 119049, Moscow, Russian Federation.
  • Shefer, Miss Kristina Chemistry. Boreskov Institut of Catalysis, Lavrentieva 5, 630090, Novosibirsk, Russian Federation.
  • Sheikh Bostanabad, Mr Ali PhD student. General Chemistry, Peoples Friendship University of Russia, Miklukho maklaya 6, 117198, Moscow, Russian Federation.
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  • Shvanskaya, Mrs Larisa Senior Reseacher. Dept. of Crystallography and crystal chemistry, Geological Faculty, Moscow State University, Leninskye Gory, GSP-2, Moscow 119992, Russia.
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  • Simonov, Dr Sergey senior research scientist. SESA, Institute of Solid State Physics, 2 Academician Ossipyan str., Moscow, 142432, Chernogolovka, Russian Federation.
  • Sinay, Dr Marina Yu. Senior Researcher. Crystal Genesis Lab., St Petersburg University, University Emb. 7/9, St Petersburg 199034, Russia.
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  • Slastnikov, Mr Victor geologist. Stachek pr.74, Saint-Petersburg, Russian Federation.
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  • Smetannikova, Dr Olga G. Senior Researcher. Department of Crystallography, St Petersburg University, University Emb. 7/9, St Petersburg 199034, Russia.
  • Smirnoff, Professor Yuri M. Head of chair. Applied Physics Chair, Department of Physics, Tver State University, Zhelyabova Str. 33, Tver 170000, Russia.
  • Smirnov, Dr Alexey E. Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Smirnov, Mr Lev Senior Researcher. Frank Lab. of Neutron Physics, Joint Institute for Nuclear Research, Dubna, Moscow Region 141980, Russia.
  • Smirnova, Ekaterina Russian Federation. Laboratory of X-ray analysis methods and synchrotron radiation, Shubnikov Institute of Crystallography, FSRC Crystallography and Photonics RAS, 59, Leninsky prospekt, 119333, Moscow, Russian Federation.
  • SMIRNOVA, Dr IRINA Senior Researcher. Institute of Solid State Physics, RAS, 142432 Moskow reg., Chernogolovka, Russian Federation.
  • Smirnova, Dr Nina Lvovna Senior Researcher, retired. Crystallography and Crystal Chemistry Chair, Department of Geology, Moscow State University, Moscow 119992, Russia.
  • Smotrakov, Dr Valery G. Senior Researcher. Institute of Physics, Southern Federal University, -, 344090, Rostov-on-Don, Russian Federation.
  • Sobolev, Dr Boris P. Head of laboratory. Laboratory of Fluoride Materials, Shubnikov Institute of Crystallography of the Russian Academy of Sciences, Leninskii prosp. 59, Moscow 117333, Russia.
  • Sokolov, Dr Alexei E. Senior researcher. Condensed matter research department, Petersburg Nuclear Physics Institute, Orlova Grove, Leningrad region, 188300, Gatchina, Russian Federation.
  • Sokolova, Dr Nataliya G. Senior Researcher, retired. ul. Pulkovskaya, 19, ap. 117, 196158, Saint Petersburg, Russian Federation.
  • Soldatov, Professor Dr Alexander Chair in Physics of nanosystems and spectroscopy. Physics of nanosystems and spectroscopy, Southern Federal University, Sorge str. 5, 344090, Rostov-on-Don, Russian Federation.
  • Soldatov, Dr Eugeni A. Associate Professor. Department of Applied Physics and Microelectronics, Nizhny Novgorod State University, Gagarina Ave. 23, Nizhny Novgorod 603600, Russia.
  • Solodovnikov, Dr Sergei F. Leading Researcher. Laboratory of Crystal Chemistry, Institute of Inorganic Chemistry, Siberian Branch of RAS, 3 Lavrentyev prosp., Novosibirsk 630090, Russia.
  • Somov, Dr Nikolay V. Senior lecturer. Physical Department, Nizhniy Novgorod State University, Gagarin av. 23a, 603950, Nizhnii Novgorod, Russian Federation.
  • Sorokin, Dr Nikolai I. Senior Researcher. Lab. of Physical and Chemical Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Sorokina, Dr Kira L. Senior Researcher. Lab. of Electron Diffraction, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Sorokina, Dr Natalia scientist. Institute of Crystallography RAS, Leninskii Prospect, 59, 119333, Moscow, Russian Federation.
  • Sotskaya, Mrs Olga young scientific worker. North-East Interdisciplinary Science Research Institute FEB RAS, Portovaya, 16, Russia, 685000, Magadan, Russian Federation.
  • Sozontov, Dr Evgueni A. Senior Researcher. Space Materials Science Research Center, of the Institute of Crystallography, Russian Academy of Sciences, 8 Akademicheskaya Str., Kaluga 248640, Russian Federation.
  • Stash, Dr Adam I. Senior Scientific Researcher. Russia 119991 GSP-1 Moscow V-334 Vavilova St 28 INEOS X-ray Laboratory.
  • Stefanovich, Dr Sergey Yu. Group leader. Karpov Institute of Physical Chemistry, 10 Obukha, Moscow 103064, Russia.
  • Stepanov, Mr Nikita researcher. Crystallography, St. Petersburg State University, 199034, St. Petersburg, Russian Federation.
  • Stepanova, Dr Alla N. Group Leader. Lab. of Crystallization from Vapor Phase, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Stepantsov, Dr Evguenii A. Senior Researcher. Lab. of Mechanical Properties of Crystals, Institute of Crystallography, Russian Academy of Sciences, 59 Leninskii pr., Moscow 117333, Russia.
  • Stiopina, Dr Nina D. Researcher. Small Angle Scattering Lab., Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Stishov, Professor Sergei M. Director of Institute. Vereschagin Institute of High-Pressure Physics, Troitsk, Moscow Region 142092, Russia.
  • Strokopytov, Dr Boris Senior Research Scientist. V. A. Engelhardt Institute of Molecular Biology, 32 Vavilova Street, 119991 Moscow, Russian Federation.
  • Suvorov, Professor Ernest Vitalievich Group leader. Laboratory of Structural Research, Institute of Solid State Physics, Russian Academy of Sciences, Chernogolovka Region, 142432, Moscow, Russian Federation.
  • Suvorova, Dr Elena Researcher. Institute of Crystallography RAS, Leninsky pr., 59, 119333, Moscow, Russian Federation.
  • Svetogorov, Mr Roman Researcher. NRC Kurchatov Institute, Akademica Kurchatova pl., 123182, Moscow, Russian Federation.
  • Tafeenko, Dr Victor Aleksandrovich Senior researcher. Lab. Structural Chemistry, Moscow State University, -, 119899, Moscow, Russian Federation.
  • Talanov, Dr Mikhail Leading Researcher. Scientific Reaserch Institute of Physics, Southern Federal University, Stachki av. 194, Rostov region, +7/45363, Rostov, Russian Federation.
  • Talanov, Professor Dr Valeriy Professor, Doctor of Chemical Science, Head of the Inorganic Chemistry Department. Chemical Technology Faculty, South-Russian State Polytechnic University, Prosvescheniya Str./346400, Rostov/ province, 7/45363, Novocherkassk, Russian Federation.
  • Talis, Dr Alexander L. Chief Researcher. Laboratory of Polymer Physical Chemistry, A.N.Nesmeyanov Institute of Organoelement Compounds of Russian Academy of Sciences, Vavilova St. 28, Moscow 119334, Russia.
  • Tamonov, Mr Andrey physicist. Frank Laboratory of Neutron Physics, Joint institute forr nuclear research, Joliot Curie str. 6, Moscow region, 141980, Dubna, Russian Federation.
  • Targonskiy, Mr Anton Researcher. Russian academy of science, FSRC Crystallography and photonics RAS, Leninskii pr. 59, 119333, Moscow, Russian Federation.
  • Tauson, Dr Vladimir L. Head of Laboratory. Institute of Geochemistry Siberian Branch of Russian Academy of Sciences, Favorskii street 1a. POB 4019, 664033, Irkutsk, Russian Federation.
  • Telegina, Dr Inna V. Chief Lecturer. Physics, Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Teslenko, Mr Pavel physics. Physics, Southern Federal University, 5, Zorge str., Rostov region/Russian Fedaration, Rostov-on-Don, Russian Federation.
  • Tikhonova, Dr Anna Andreyevna Senior Researcher. Lab. of Electron Diffraction, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., 117333, Moscow, Russian Federation.
  • Timofeev, Mr Vladimir IC RAS. Leninskii pr., 59, 119333, Moscow, Russian Federation.
  • Tkachev, Dr Valeri V. Senior Researcher. Branch Institute of Chemical Physics, Russian Academy of Sciences in Chernogolovka, 142432 Chernogolovka, Moscow Region, Russia.
  • Tolstikhina, Dr Alla L. Head of group. Shubnikov Institute of Crystallography RAS, Leninsky pr. 59, 119333, Mosvow, Russian Federation.
  • Tolstikova, Miss Alexandra Student. 9/4-172 Pervomayskaya str., Moscow region, 141701, Dolgoprudny, Russian Federation.
  • Tomashpolsky, Professor Yuri Ya. Vice-Director. Karpov Institute of Physical Chemistry, 10 Obukha St., Moscow 103064, Russia.
  • Trebushinin, Mr Andrei Researcher. Budker Institute of Nuclear Physics, Prospekt Akademika Lavrent'yeva, 11, Novosibirsk oblast, 630090, Novosibirsk, Russian Federation.
  • Treivus, Dr Eugene (Eugenij, Evgenii) Borisovich Chief Researcher, retired. Crystal Genesis Laboratory, St Petersburg University, University Emb. 7/9, St Petersburg 199034, Russia.
  • Trofimov, Mr Victor B. Senior Researcher. Department of Crystallography, St Petersburg University, University Emb. 7/9, St Petersburg 199034, Russia.
  • Trubkin, Dr Nikolay V. Senior Researcher. Laboratory of Electron Microscopy, Institute of Geology of Ore Deposits, Petrology, Mineralogy and Geochemistry, Russian Academy of Sciences (IGEM RAS), Staromonetny 35, 109017 Moscow, Russia.
  • Trushin, Dr Vladimir N. Senior Researcher. Nizhnii Novgorod State University, 23 Gagarin Av., 3 - NIFTI, office 402, 603950, Nizhnii Novgorod, Russian Federation.
  • Trushina, Ms Daria junior researcher. Nakhimovskii prospect, 117335, Moscow, Russian Federation.
  • Tsirelson, Professor Dr Vladimir Professor, Head of the Quantum Chemistry Department. Mendeleev University of Chemical Technology of Russia, 9 Miusskaya Square, Moscow 125047, Russia.
  • Tsybulya, Dr Sergey V. Senior Researcher. Boreskov Institute of Catalysis, Laboratory of Structure Methods, 5 Lavrentieva Pr., Novosibirsk 630090, Russia.
  • Tsymbarenko, Dr Dmitry Senior Researcher. Leninskie gory, 1-3, Moscow, 119991, Russian Federation, Lomonosov Moscow State University, Chemistry department, Inorganic chemistry division.
  • Tugaeva, Ms Kristina phD Student. Institute biochemistry A.N.Bach, Leninskyi pr. 33, 119071, Moscow, Russian Federation.
  • Tyunina, Mrs Elena research. Solid State Physics and Chemistry, Moscow State Academy of Fine Chemical Technology, 86 Vernadsky pr., 119571, Moscow, Russian Federation.
  • Urusova, Mrs Darja V. Researcher. Institute of Crystallography RAS, Leninskii pr., 59, 119333, Moscow, Russian Federation.
  • Vakhrushev, Professor Dr Sergey head of neutron research lab. Ioffe Institute. Neutron research lab., Ioffe Institute, 26 Politekhnicheskaya, 194021, St. Petersburg, Russian Federation.
  • Vasiliev, Dr Alexander D. Group leader. Laboratory of Crystal Physics, Institute of Physics, Siberian Dept., Russian Academy of Sciences, Krasnoyarsk 660036, Russia.
  • Vasiliev, Dr Alexandr L. Senior Researcher. Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Vasilovskiy, Mr Sergey G. Researcher. Laboratory of Neutron Physics, Joint Institute for Nuclear Research, Leningradskaya, 14, Moscow region, 141980, Dubna, Russian Federation.
  • Veremeichik, Dr Tamara F. Senior Researcher. Lab. of Crystallophysics, Shubnikov Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky Pr., Moscow 117333, Russia.
  • Vereshchagin, Mr Oleg PhD-student. Crystallography, Saint-Petersburg State University, Universitetskaya nab. 7-9, 190000, Saint-Petersburg, Russian Federation.
  • Vergasov, Dr Vladimir L. Senior Researcher. Lab. of Electron Diffraction, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Vigdorchik, Dr Asya G. Senior Researcher, retired. Institute of Crystallography, Laboratory of X-ray Structure Analysis Russian Academy of Sciences 59 Leninsky pr. Russia, 117333, Moscow, Russian Federation.
  • Vinogradov, Dr Alexander V. Junior Researcher. Lab. of Acoustooptics of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Virovets, Dr Alexander V. Seniour Researcher. Lab. of Crystal Chemistry, Institute of Inorganic Chemistry Siberian Branch, Russian Academy of Sciences, 3 Lavrentyev prosp., Novosibirsk 630090, Russia.
  • Vlasov, Dr Vasily Platonovich Senior Researcher. Lab. of Elementary Processes of Crystal Growth, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Volkov, Dr Vladimir V. Senior Researcher. Lab. of Crystallophysics, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky Pr., Moscow 117333, Russia.
  • Volochaev (Volotchaev), Dr Vadim senior scientist. Chemistry Department, Southern Federal University, Zorge 7, 344090, Rostov-on-Don, Russian Federation.
  • Volodin, Alexander Student. Lab 201, INEOS RAS, Vavilova street, 28, 119991, Moscow, Russian Federation.
  • Vologzhanina, Dr Anna V. senior researcher. X-Ray structural centre, A.N. Nesmeyanov Institute of Organoelement Compounds of Russian Academy of Sciences, 28, Vavilova str., 119991, Moscow, Russian Federation.
  • Voloshin, Dr Alexey E. Head of Laboratory. Shubnikov Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Voronkova, Dr Valentina I. Leader Researcher. Chair of Polymer and Crystal Physics, Physics Department, Moscow State University, Moscow 119992, Russia.
  • Voronova, Ms Evgeniia A.N.Nesmeyanov Institute of organoelement compounds. Laboratory of Metal Hydrides, A.N.Nesmeyanov Institute of organoelement compounds, 28, Vavilova str., 119991, Moscow, Russian Federation.
  • Vorontsov, Mr Dmitry A. engineer. Nizhny Novgorod State University, Avenue Gagarin, 23, 603950, Nizhny Novgorod, Russian Federation.
  • Voytekhovsky, Dr Yury Research Associate. Geological Institute, Kola Science Centre of RAS, 14 Fersman Street, Murmansk reg., 184209, Apatity, Russian Federation.
  • Vtyurin, Professor Aleksander Deputy Director. Kirensky Institute of Physics, Akademgorodok, 660036, Krasnoyarsk, Russian Federation.
  • Wevtop, Dr Wertu Sropre. Russsssss, 345767, Moscowwww, Russian Federation.
  • Yakovleva, Miss Ekaterina Ph. D. Student. Department of Crystallography and Crystal Chemistry, Geological Faculty, Moscow State M.V. Lomonosov University, Leninskie gory, 1, 119992, Moscow, Russian Federation.
  • Yakubovich, Dr Olga V. Leading Researcher. Department of Crystallography, Geological Faculty, Moscow State University, 119899 Moscow, Russia.
  • Yakunin, Dr Andrei N. Researcher. Laboratory of Polymer Structure, Karpov Institute of Physical Chemistry, ul. Vorontsovo Pole 10, 105064, Moscow, Russian Federation.
  • Yakushkin, Dr Eugene D. Researcher. Laboratory of Electromechanical Investigations of Crystals, Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Yamnova, Dr Natalya A. Senior Researcher. Department of Crystallography and Crystal Chemistry, Faculty of Geology, Moscow State University, Moscow 119899, Russia.
  • Yanovsky, Dr Alexander I. Senior Researcher. X-ray Structural Center of the Russian Academy of Sciences, Institute of Organoelement Compounds, Russian Academy of Sciences, 28 Vavilov St., Moscow 117813, Russia.
  • Yanusova, Dr Ludmila G. Researcher. Small Angle Scattering Lab., Institute of Crystallography, Russian Academy of Sciences, Leninsky pr. 59, Moscow 117333, Russia.
  • Yatsenko, Dr Alexandr Vasilievich Professor. Lab. Structural Chemistry, General Chemistry Faculty, Chemistry Dept., Moscow State University, Moscow 119899, Russia.
  • Yushina, Dr Irina South Ural State University. SEC Nanotechnology, South Ural State University, Lenin avenue, 76, 454080, Chelyabinsk, Russian Federation.
  • Zadorozhnaya, Dr Ludmila A. Researcher. Lab. of Crystallization from Gas Phase, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Zaitseva, Dr Ekaterina V. Lecturer. Nizhnii Novgorod State University, Gagarin av. 23, building 3, 603950, Nizhnii Novgorod, Russian Federation.
  • Zakalyukin, Dr Ruslan M. senior scientist. Department of Crystallization from Solutions laboratory of Crystallization from High-Temperature Solutions, Shubnikov Institute of Crystallography of the Russian Academy of Sciences, Leninskii pr. 59, 117333, Moscow, Russian Federation.
  • Zakharchenko, Dr Irina N. Senior Researcher, chief of laboratory. Nanotechnology, Southern Federal University, Zorge St 5, 344090, Rostov-on-Don, Russian Federation.
  • Zakharov, Dr Boris A. Researcher. lab. No 117, Federal Research Center Boreskov Institute of Catalysis, Lavrentiev Ave. 5, Novosibirsk area, 630090, Novosibirsk, Russian Federation.
  • Zakharov, Dr Boris G. Head of Laboratory; Director. Laboratory of X-ray Structure Analysis, Kaluga Branch of Institute of Crystallography, Russian Academy of Sciences, 2 Akademicheskaya Str., Kaluga 248640, Russia.
  • Zakharov, Dr Maxim Alexandrovich Assistant Professor (Dozent). general chemistry division, lab of structural chemistry, Moscow State University, Chemistry department, Leninskie gory, 119991, Moscow, Russian Federation.
  • Zakharov, Mr Nikita Student. January 9th Street House 99, Samara region, 445007, Togliatti, Russian Federation.
  • Zakharov, Dr Robert G. Senior Researcher. Institute of Metallurgy, Urals' Division of the Russian Academy of Science, 101 Amundsen Str., 620016, Ekaterinburg, Russian Federation.
  • Zaloga, Mr Aleksandr Research engineer. X-ray methods laboratory, Siberian Federal University, pr. Krasnoyarsky rabochiy, 95, Krasnoyarskiy kray, 660025, Krasnoyarsk, Russian Federation.
  • Zamyatin, Mr Dmitry Phd Student. Laboratory of physical and chemical research methods, Institure of geology and geochemistry, Pochtovy street, 7, The Ural, 620075, Ekaterinburg, Russian Federation.
  • Zanin, Dr Igor E. senior lecturer. Voronezh State University, University sq., 1, 394006, Voronezh, Russian Federation.
  • Zaporozhets, Dr Marina resercher. electron crystallography, Shubnikov Institute of Crystallography RAS, 59, Leninsky prospekt, 119333, Moscow, Russian Federation.
  • Zasurskaya, Dr Larissa Alexandrovna Senior researcher. Lab. of Crystal Chemistry, Chemical Dept., Moscow State University, Moscow 119991, Russian Federation.
  • Zavodnik, Dr Valery E. Chief Researcher. X-ray Laboratory, Karpov Institute of Physical Chemistry, 10 Vorontsovo Pole., 103064 Moscow, Russia.
  • Zayakina, Dr Nadezhda Viktorovna Senior Researcher. Institute of Diamond and Precious Metals Geology, Siberian Department, Russian Academy of Sciences, Lenin pr. 39, Yakutsk 677007, Russia.
  • Zharikov, Professor Dr Evgenii Vasilevich Head of Department of Crystals Chemistry and Technology. Laser Materials and Technology Research Center at GPI, Prokhorov General Physics Institute of RAS, 9 Miusskaya sq., 125190, Moscow, Russian Federation.
  • Zhdanova, Dr Lyudmila Ivanovna Senior scientific collaborator. Udmurt State Universiti, Krasnogeroiskaya Str. 71, Izhevsk 426034, Russia.
  • Zhigalina, Dr Victoria researcher. Electron microscopy lab, FSRC Crystallography and Photonics RAS, Leninskiy prospect, 119333, Moscow, Russian Federation.
  • Zhmurova, Dr Zinaida I. Chief Researcher. Laboratory of Physical and Chemical Analysis, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky pr., Moscow 117333, Russia.
  • Zhukhlistov, Dr Anatoly P. Leading Researcher. Institute of Geology of Ore Deposits, Petrography, Mineralogy and Geochemistry PAS, Staromonetnii per., 35, Moscow, 119017, Russian Federation.
  • Zhukhlistova, Dr Nadezhda E. Senior researcher. Laboratory of Biocrystal Structure, Institute of Crystallography, Russian Academy of Sciences, 59 Leninsky prosp., Moscow 117333, Russia.
  • Zibrov, Dr Igor P. Head of Analytical Lab.. Analytical Lab., Institute for High Pressure Physics, Russian Academy of Sciences, Kaluzhskoe highway, 14, Troitsk, Moscow Region 142190, Russia.
  • Zinchenko, Mrs Elena N. Researcher. Voronezh State University, University sq., 1, 394006, Voronezh, Russian Federation.
  • Zinenko, Dr Victor I. Chief Researcher. Lab. of Crystal Physics, Institute of Physics, Siberian Dept., Russian Academy of Sciences, Krasnoyarsk 660036, Russia.
  • Zlokazov, Dr Victor B. Senior Researcher. Frank Lab. of Neutron Physics, Joint Institute for Nuclear Research, Dubna, Moscow Region 141980, Russia.
  • Zolotarev, Pavel Junior Researcher. Department of Physical Chemistry, Samara University, Ac. Pavlov street 1, 443011, Samara, Russian Federation.
  • Zorina, Dr Leokadia research scientist. Institute of Solid State Physics, RAS, Institutskii prospect, 15, 142432, Chernogolovka, Russian Federation.
  • Zubenko, Dr Vasily Vasilyevich Associate Professor. Physics, Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Zubkova, Dr Natalia V. associate professor. Geology, Moscow State University, Leninskie Gory, 1, 119992, Moscow, Russian Federation.
  • Zvereva, Dr Irina A. Associate Professor. Laboratory of Thermodynamic and Kinetic studies of Nanostructured Materials, Saint Petersburg State University, Petrodvoretz, Universitetskiy pr., 26, 198504, Sankt Petersburg, Russian Federation.
  • Zviagina, Dr Bella B. Senior Researcher. Lab. for Investigation of Rock-Forming Minerals by Physical Methods, Geological Institute, Russian Academy of Sciences, Pyzhevsky per. 7, Moscow 119017, Russia.

Russian Federation

This is a list of forthcoming meetings in Russian Federation that are recorded in the IUCr Calendar of Events. Please let us know of any that are missing by completing this form or sending an email to forthcoming.meetings@iucr.org.

Reports of past activities in Russia

All events

This is a concise listing of all events in this country that are associated with the International Year of Crystallography 2014 and its follow-up initiatives.

2nd Oct 2013 Workshop "Frontiers of crystallography" Novosibirsk
21st Oct 2013 Second All Russian Scientific Conference Novosibirsk
30th Oct 2013 Public lecture for children from secondary schools of Novosibirsk Novosibirsk
7th Feb 2014 Crystals and Planets Novosibirsk
15th May 2014 Novosibirsk Science Festival EUREKA!FEST Novosibirsk, Akademgorodok
15th May 2014 3rd School for young scientists on physics of nanostructured and crystalline materials Nizhni Novgorod
2nd Jun 2014 25th Russian Conference on Electron Microscopy Chernogolovka, Moscow region
9th Jun 2014 18th International Symposium on the Reactivity of Solids Saint-Petersburg
12th Aug 2014 Topological methods for expert systems in materials science Samara
22nd Sep 2014 The International Workshop on Smart Nanomaterials 2014: Modeling, Synthesis, Diagnostics Rostov-on-Don
16th Dec 2014 XXXIII Scientific Readings named after Academician N.V. Belov Nizhni Novgorod
9th Feb 2015 Molecular materials: from fundamentals to applications Novosibirsk
Papers about crystallography in Priroda magazine - II Moscow
Papers about crystallography in Priroda magazine - Part II
Papers about crystallography in Priroda magazine Moscow A set of papers of some scientists of A.V.Shubnikov Institute of Crystallography of the RAS written specially on the occasion of IYCr for Priroda magazine (in Russian; annotations in English).

This Special Report was published in the IUCr Newsletter, Vol. 12, Nos. 2 and 4 (2004).

Crystallography in Russia

Shubnikov Institute of Crystallography, Russian Academy of Sciences: 1940-2000

Foundation of the Institute

[A. V. Shubnikov] A. V. Shubnikov
[B. K. Vainshtein] B. K. Vainshtein
[M.V. Kovalchuk] M. V. Kovalchuk
Aleksei Vasil'evich Shubnikov is justly considered one of the founders of the science on growth, structure, and properties of crystals. He initiated the physical direction in crystallography, broadened its horizons from the study of crystals within the framework of traditional mineralogy to the interdisciplinary science including physics, chemistry and mathematics. In 1934 Shubnikov organized the Crystallographic Section at the Lomonosov Institute of Geochemistry, Mineralogy, and Petrography in Moscow. In 1937, the crystallographic section was reorganized into the independent Laboratory of Crystallography of the USSR Academy of Sciences within the Dept. of Geological-Geographical Sciences. In November 1943 the Laboratory became the Institute of Crystallography in the Dept. of Physical-Mathematical Sciences of the USSR Academy of Sciences. A.V. Shubnikov was the first Director, Boris K. Vainshtein was the head of the Institute from 1962 to 1996, and Mikhail V. Kovalchuk has been the Director since 1998.

Development of scientific directions

The Institute of Crystallography was actively engaged in the fields of crystal symmetry and morphology, X-ray diffraction analysis, crystal growth and the synthesis of quartz. In 1939, N.N. Sheftal suggested a method for growing large crystals of Rochelle salt and high-quality piezoelectrics necessary for constructing sensitive piezoelectric devices for use in the war. In the 1940s, Shubnikov put forward a concept of antisymmetry for studying magnetic properties of crystals and N.V. Belov composed a theory of close packings and performed detailed X-ray diffraction analysis of the atomic structures of silicate minerals. In 1945, G.G. Lemmlein found a spiral relief in crystal faces associated with the helicoidal structure of the crystal lattice. Methods for studying crystal structure were being rapidly developed at the Institute. Vainshtein used Fourier synthesis to calculate the distribution of electrostatic potentials in crystal lattices based on experimental electron diffraction data (1949). Vainshtein and Z.G. Pinsker determined the structure of paraffin, and the localized hydrogen atoms within it. In the 1950s, S.A. Semiletov and coworkers obtained fundamental results on the mechanism of homoepitaxial growth of thin germanium films. At the same time S.K. Popov designed an automated industrial apparatus for growing ruby rods. In 1940s-1950s, N.V. Belov and his coworkers initiated studies on the crystal chemistry of silicates related to geochemical and geophysical processes and the production of cements, glasses, and ceramics. Their studies were used to develop low-temperature cement and new types of concrete. In 1951, Shubnikov published Symmetry and Antisymmetry of Finite Figures, in which he discussed the notion of four-dimensional crystallography.

[N. V. Belov] N. V. Belov
[TR5 spectrometer]TRS triple-crystal spectrometer
[spiral growth step on SiC] A spiral growth step on the silicon carbide surface.
Sheftal and coworkers synthesized dislocation-free germanium single crystals and put forward the concept of artificial epitaxy for obtaining oriented films on amorphous substrates. In 1969, the scientists of the Institute grew oriented systems of whiskers on single-crystal substrates, a method useful for the production of semiconductors. V.L. Indenbom found (1958) that the structural transformation observed in Rochelle salt is a second-order phase transition. Scientists at the Institute, headed by I.S. Zheludev and L.A.Shuvalov, worked on the general laws of formation of structures possessing spontaneous polarization and found new ferroelectric materials.

B.N. Grechushnikov, in cooperation with G.I. Distler, worked on the theory of Fourier-spectroscopy and designed and constructed a Fourier spectrometer. This instrument obtained well-resolved illumination light spectra from the Saturn disk and rings.

In 1962, the group, headed by Kh.S. Bagdasarov, built a stably operating laser. In 1972, laser radiation from chromium ions in garnets was achieved. At the beginning of the 1960s, the scientists of the Institute determined the structures of synthetic analogues of a protein (a complex polypeptide), crystallized enzymes into tubes with monomolecular walls, and determined the structure of leghemoglobin. In the 1980s, the scientists of the Institute developed an experimental approach to high-pressure studies of crystals using diamond anvils, increasing the range of attainable pressures (up to 100 GPa) and broadening the spectrum of problems solvable by this method.

Fundamental studies in the theory of dislocations, the physics of plasticity, the theory of phase transitions in crystals, and the theory of symmetry were pursued. In particular, the existence of improper phase transitions was predicted. The studies of the statistical kinetics of spiral-layer crystallization helped to clarify many processes. In 1990s the scientists of the Institute developed the theory of electrooptical and ferroelectric properties of liquid crystals and designed many applicable devices.

Development of technology of crystal synthesis

L.M. Belyaev and his coworkers studied the synthesis of organic and inorganic crystal-scintillators with high scintillation efficiency. In the 1960s, A.A. Shternberg worked out the industrial synthesis of a rock crystal, piezoelectric quartz.

A method for horizontal crystallization for growing refractory single crystals was developed along with the technologies for growing large almost perfect single crystals of yttrium-aluminum garnet, sapphire, and yttrium aluminate. Industrial facilities for growing single crystals were constructed.

Methods of the thermal-compression junction and creation of solid-phase junctions of laser crystals that guarantee high optical quality of the interfaces were developed. New crystallization apparatus for growing crystals in space were also constructed, and crystallization experiments were performed on water-soluble crystals under the conditions of microgravity at the Salyut-5 orbital station (1976).

[carnation mottle virus] Atomic structure of a Carnation Mottle virus.
[synthetic crystals] Synthetic crystals.

Instrument design

A series of specialized diffractometers have been designed at the Institute including the TRS triple-crystal X-ray diffractometer, the KARD-4 automated coordinate X-ray diffractometer, the RED-EL four-circle X-ray diffractometer, the DAR family of automated X-ray diffractometers, and the AMUR series of X-ray small-angle diffractometers. An automated 512-channel diffractometer for proteins was also constructed. In cooperation with the Laboratory of High Energies of the Joint Institute for Nuclear Research (JINR) in Dubna, a two-dimensional proportional chamber for the automated KARD diffractometer for studying protein single crystals was designed. Methods for studying polycrystalline materials, polymers and liquid crystals in X-ray diffractometers with two-dimensional detectors were also developed.

The Institute of Crystallography in the 21st century

New scientific priorities

At present, the Shubnikov Institute is focusing on the following problems:

  • Creation of new crystals, films, and structures with specific properties;
  • The study of the structures and properties of condensed matter using X-ray and synchrotron radiation, neutrons, and electrons;
  • Further development of existing instruments and methods and creation of new ones;
  • Study of properties of biological materials and organic systems;
  • Study of condensed matter under microgravity;
  • Study of surfaces, subsurface layers, interfaces, thin films, and track membranes;
  • Development of X-ray optics; and
  • Design and construction of apparatus for crystal growth.

The Institute also participates in the following projects of the Federal Scientific and Technological Program:

  • Physics of Radiation,
  • Condensed Matter,
  • High-Precision Measurements,
  • Quantum and Nonlinear Processes,
  • Physics of Solid Nanostructures,
  • Information Technologies and Electronics,
  • New Materials and Chemical Products,
  • Scientific Instrument Engineering.

Within the framework of the Russian Academy of Sciences, the Institute performs work on laser systems, strongly correlated electrons, nanomaterials and nanotechnologies. The Institute of Crystallography participates in the Federal Space Program of Russia.

Shubnikov participated in the organization of the lUCr and suggested the title Acta Crystallographica for its printed edition. Belov served as the IUCr President from 1966 to 1969, Vainshtein and V.I. Simonov were Vice-Presidents in 1975-1978 and 1984-1987, respectively. The Institute of Crystallography cooperates with more than twenty foreign scientific organizations participating in numerous interacademic and interinstitute agreements. The Institute holds annual Shubnikov, Vainshtein, and Belov lectures.

Structural studies

[growth on icosahedral quasiquartz] Computer simulation of growth of an icosahedral quasiquartz.
Kovalchuk and his laboratory developed different surface-sensitive and phase-sensitive X-Ray diffraction methods, among them - new modification of X-ray Standing Waves (XRSW) with photoelectrons. This method combines high resolution X-ray diffraction and spectroscopy. The XRSW method has been modified for the structural characterization of multicomponent crystals, semiconductor heterostructures, multilayer X-ray mirrors, X-ray waveguide structures, organic multilayer systems based on Langmuir-Blodgett films, and protein-lipid systems on solid and liquid substrates. Coherent interaction of X-ray and synchrotron radiations with condensed matter in the range of hard wavelengths have been studied. XRSWs with periods varying from 0.001 to 100 nm based on the phenomena of double- and multibeam diffraction, total external reflection, etc. have been developed.

M.V. Kovalchuk and S.I. Zheludeva used fluorescence in the range of total external reflection of X-rays for localization of ions inside organic multilayers. The study of protein-lipid systems on liquid surfaces and solid substrates revealed the effect of drugs on heavy atom positions. Today scientists at the Institute actively use synchrotron radiation in many fields of modern crystallography and they play a leading role in researches at Kurchatov Center of Synchrotron Radiation (KCSR).

Studies of the semiconductor Inx Ga1-x As/GaAs demonstrated the value of X-ray diffraction in characterization of multilayer systems including determination of the thickness and compositions of individual layers, interface structures, and defects in the layers. Computer simulation of the growth of icosahedral quasicrystals has been performed. New types of diffraction reflections in crystals of germanium and a germanium-silicon alloy have been predicted. Defects arise because of distortion of the electronic state of germanium atoms by thermal vibrations and point defects. Such reflections have been observed in technologically important crystals and alloys. The group, headed by N.A. Kiselev, used high-resolution electron microscopy to study nanotubes with multilayer cylindrical walls and walls consisting of conic graphene layers and surface-modulated walls. L.A.Feigin's laboratory had a large contribution in the development of small angle scattering methods (theory, experiments and instrumentations) in application of X-R reflectometry in the study of different bioorganic materials.

Shortly before the 60th Jubilee of the Institute, a newly discovered mineral was officially named IKRANITE by the International Mineralogical Assn. Five other minerals have been named after scientists of the Institute: shubnikovite, belovite, lemmleinite, stishovite, and rastsvetaevite. The Institute regularly holds national conferences on crystal growth and annual schools on electron microscopy.

New crystalline media

[nanocrystalline zinc oxide powder] Nanocrystalline zinc oxide powder.
[silicon whiskers] (a)
[nanodimensional tip] (b)

(a) Silicon whiskers, (b) HREM image of a nanodimensional tip.
Using hydro-thermal methods, nanocrystalline ZnO powders were obtained with luminescence characteristics significantly exceeding those of powders obtained by traditional methods (L. Demianetz group). The sol-gel synthesis in nonaqueous media produced cathode materials for lithium batteries. A method of diamond deposition onto silicon tips has been developed to enhance the autoemission of silicon cathodes. Systems of whiskers are used as the tips for autoemission cathodes. Single-crystal silicon wires with a diameter of 5 nm have been obtained, which are promising for potential nanoemitters.

A Gd-containing fast scintillator has been suggested in the fluoride family (together with the Russian Research Center Kurchatov Institute). Such a scintillator is very promising for recording low-energy neutrinos. Langasites, a new family of highly efficient piezoelectrics, has been discovered by Pisarevsky's group in cooperation with Moscow State University.

Bioorganic materials science

[R. communis agglutinin] Three-dimensional structure of Ricinus communis Agglutinin at a resolution of 2.5 Å.
The three-dimensional structure of a Ricinus communis Agglutinin was determined at a resolution of 2.5 Å using synchrotron radiation. The proteins of this group are used as stimulators of the immune system. The Institute developed a method and apparatus for protein crystallization that can also be used for growth of biocrystal films under the conditions of microgravitation. The Institute has developed a method for interactive modeling of structures of bio-polymer molecules in solution based on data from small-angle X-ray and neutron scattering. This allows one to determine not only the shape but also the inner structure of the particles, to analyze the domain structure and the dynamics of macromolecules in solution, and to reconstruct the structure of protein molecules in solution. Software designed at the Institute is used in many laboratories around the world.

Scientific engineering

[PRO station] PRO station of precision X-ray optics.
[KROT setup] KROT setup for crystal growth.
Numerous instruments have been developed by Kovalchuk and co-workers for use on the synchrotron facilities at the Kurchatov Synchrotron Radiation Center including the experimental station for medical diagnostics (Mediana), protein crystallography (Belok), precision X-ray optics (PRO), material science (RKFM) and EXAFS station. Instruments for robotic growth of large (75 mm diameter) high quality single crystals have been perfected. Of particular note are crystals of sapphire-titanium (Al2O3:Ti3+) used in a new generation of terawatt lasers in the femtosecond range

Studies of physical properties

[AFM topograph] AFM topograph image of a portion of the polar (010) surface of a ferroelectric triglycine sulfate crystal.
The effect of high pressures on the structural, magnetic, transport, and optical properties of magnetic materials is studied in high-pressure chambers with diamond anvils. Magnetic-nonmagnetic and dielectric-metal phase transitions, ferroelectric properties of ultrathin Langmuir-Blodgett polar films, and polarization switching in films of a P(VDF-TrFE) copolymer have been explored.

Active lithium niobate (a nonlinear optical material) was found to have impurities (Mg, Zn, In, etc.). By varying the doping level, it is possible to vary these properties. Magnetically stimulated strengthening of crystals manifests itself as a decrease in the dislocation mobility under the joint action of an applied mechanical load and a magnetic field. Atomic force microscopy (AFM) was found to be an efficient way to study the domain structure of polar surfaces of ferroelectrics. Analysis of the data revealed the effect of crystal-lattice distortions on dislocation mobility and a new type of dynamics of plastic flow in crystalline materials.

Track membranes

Track membranes allow one to create tip electrode nanostructures that release molecular hydrogen 100 times more intensely than traditional electrode systems. The Institute has obtained new products based on track membranes including systems for monitoring drinking water, systems of track-pore room and respirators based on the principle of diffusion gas exchange, tip structures for Raman spectroscopy and for increasing heat removal from reactor surfaces, and membranes for purification of crystallization solutions.

Innovative projects

The experience of the Institute in solid-state physics and the development of technologies of crystal growth paved the way for participation in the State project on the development of an industry of synthetic dielectric crystals and their products. About twenty Russian institutes, industrial enterprises and companies participate in this project. The Institute coordinates the development of new instruments and technologies for the production of synthetic dielectric crystals. The new technology is based upon fundamental advances made by the Institute and benefit from past experience and industrial achievements in the field of growth and processing of crystals, and the manufacture of various crystal-based products.

Contact: Mikhail V. Kovalchuk (koval@ns.crys.ras.ru) Translated by L.I. Man

Inorganic Crystal Chemistry at Moscow State University

[periodic table] Chemists Holiday - Sr Day - celebrated at the Chemistry Department of Moscow State University. Probably the largest Mendeleev’s Periodic Table of Elements.
[inorganic chain] The crystal structure of Sr2MnGaO5 with an ...LRLR... type of chain alternation (Pcmb space symmetry). Two different projections of the GaO4 tetrahedra correspond of two different kinds of the tetrahedral chains.
[inorganic structure] Crystal structure of Sr0.7Y0.3CoO2.62. Layers with Co2O6 octahedra alternate with oxygen-deficient layers.
[staff and students] The staff and students of the Inorganic Crystallochemistry Laboratory. From left to right front row: Yu. Velikodny, E. Antipov, A. Abakumov, S. Putilin; middle row: M. Rozova, R. Panin, O. Dyachenko; back row: R. Shpanchenko, S. Istomin, O. Lapshina, N. Khasanova, V. Govorov, V. Koutsenko, A. Alekseeva, A. Mironov.
For 50 years, the Inorganic Crystal Chemistry Laboratory in the Chemistry Department of Moscow State University has performed a full range of scientific studies from the syntheses of compounds to investigations of their structures and physical properties. The laboratory, previously directed by Yuri P. Simanov and Leonid M. Kovba, has been led by Evgeny V. Antipov since 1996.

The laboratory's goals involve the synthesis of new compounds, determination of their three-dimensional structures and correlation of structure and properties. Powder diffraction is used for phase analysis and cell parameter determination, followed by structure solution from either powder or single crystal X-ray data (XRD). For problem cases electron diffraction (ED) together with high resolution electron microscopy (HREM) and/or neutron diffraction are used. Sometimes other methods help to answer specific questions on structural details, and throughout the process measurements of physical properties are performed by collaborators.

The targets of study over the years have been mainly complex oxides. Intensive studies of superconducting complex cuprates in 1987 resulted in the discovery of a family of mercury based cuprates that exhibits the highest known transition temperature. In 1994, this work received the Lomonosov Award of the Moscow State University and the Superconductivity Award of Excellence given by the World Congress on Superconductivity. Our discoveries have included various superconducting copper based oxides, oxycarbonates, oxyfluorides, and superconducting bismithates. When Sr1-xKxBiO3 was synthesized under high pressure it was found that both the symmetry of the unit cell and its superconducting properties depend on potassium content. The highest superconducting transition temperature was found for the composition Sr0.44K0.56BiO3 when the phase crystallizes in a tetragonal unit cell.

The search for substances with colossal magnetoresistance effects resulted in the synthesis of A2GaMnO5+δ (A=Sr, Ca, δ ≤ 0.5) phases for the first time. These phases undergo interesting structural and magnetic phase transitions during the oxidation process. It has been shown that compounds with a Brownmillerite type structure crystallize in different space groups. Only the use of electron microscopy and a 3+d dimensional crystallographic approach helped to describe their structures correctly. The space group depends on the orientation of tetrahedral GaO4 chains and their ordering in adjacent layers. Sometimes, such ordering occurs in a rather complicated manner forming commensurately modulated structures. For the Sr and Ca phases the insertion of extra oxygen resulted in the suppression of Jahn-Teller distortion for MnO6 octahedra, a change of Ga coordination from tetrahedral to octahedral, and an increase of unit cell symmetry from orthorhombic to tetragonal.

The study of complex cobalt oxides as potential mixed conductors led to the discovery of Sr0.7Y0.3CoO2.62 which has a perovskite-related crystal structure. Its tetragonal unit cell is formed of alternating cobalt oxygen layers. Half of the layers consist of CoO6 octahedra, others are oxygen deficient tetrahedra with one additional oxygen at the long distance. The structure is considered as intermediate between brownmillerite and perovskite.

Many of these studies would not have been possible without our collaborators. We are grateful to Arne Magneli and Lars Kihlborg (Stockholm University) who were very helpful during the early 90's, a difficult time for Soviet and Russian science. Massimo Marezio and his colleagues (CNRS, France) have been collaborators in the syntheses and structural studies of superconducting complex copper oxides. Phillip Coppens (SUNY, USA) and Vaclav Petricek (Institute of Physics, Czech Rep.) helped us to understand what modulated structures are. Electron diffraction and high resolution electron microscopy studies are still carried out with Gustaaf Van Tendeloo and co-workers (EMAT, Belgium). Structure refinements from neutron data are based on experiments done in Dubna in the Joint Institute on Nuclear Research by the group of Anatoly Balagurov.

Information about the Inorganic Crystal Chemistry Laboratory can be found at www.icr.chem.msu.ru .
Contact: Evgeny Antipov (antipov@icr.chem.msu.ru)

Structural Chemistry, Moscow State University

Under the direction of Leonid A. Aslanov (aslanov@struct.chem.msu.ru), four main directions of research are being pursued in the Laboratory of Structural Chemistry at Moscow State University:

A. The laboratory is involved in the development of methods for structural characterization of polycrystalline materials from powder data in collaboration with H. Schenk (University of Amsterdam)[1]. Two molecular structures solved recently from powder diffraction data demonstrate our achievements in this area.

[thermal isomerization]
[h-bonding] Hydrogen bonding in dG.
1. Evidence for thermal isomerization of compound (I), C24H15N5O2, into compound (II) (see Scheme) has been obtained[2].

2. Elucidation of three-dimensional solid state structures of two modifications of doxazosin mesylate[3], a commonly used antihypertensive agent, clearly showed the N1 protonation site in anhydrous (A) and hydrated (dG) solid forms, establish the conformations of the doxazosin molecule and define the hydrogen bonding in both forms.
Contact: Vladimir V. Chernyshev (vladimir@struct.chem.msu.ru)
[stacks]
B. Organic compounds containing from two to four cyano-groups are widely used in preparation of photochromic materials and anticancer drugs. Such compounds contain several active chemical centers and participate in a diversity of chemical reactions. A new kind of organic anion, 3-cyano-4-(dicyanomethylene)- 5-oxo-4,5-dihydro-1H-pyrrol-2-olate, was synthesized as a result of the reaction of tetracyanocyclopropane derivatives with an iodide anion. In the crystals of anion-containing organic salts there are various kinds of stacks due to π-π anion-cation or anion-anion interactions[4].
Contact: Victor A. Tafeenko (tafeenko@biocryst.phys.msu.su)
[scheme]
[PAR] Sodium pyridylazoresorcinolate monohydrate (PAR) – common metal indicator studied by X-ray powder diffraction.
C. The laboratory studies pathways for mapping reactions of mesoionic (MESOmeric+IONIC) compounds. Mesoionic systems may be transformed to highly reactive oxo(thio-, imino)[3,2-a]pyridinium cations which, in turn, undergo a variety of ring opening/transformation reactions leading to novel classes of heterocyclic compounds. For example, mesoionic azolopyridines are related to the family of condensed munchnones: a) X=S; Y=S, O, NR; b) X=O; Y=S, O, NR, c) X=NR; Y=S, O, NR. Crystal and molecular structures of novel anaesthetic drugs based on quiniline derivatives, novel pesticides based on urea heterocyclic derivatives, and novel radioprotectors based on pyrimidine derivatives were determined by both X-ray and neutron diffraction.
Contact: Victor B. Rybakov (rybakov@struct.chem.msu.su)

D. A number of the traditional dyes and pigments, as well as modern materials for electrooptical and photonic applications and laser dyes, have been studied by means of single crystal and powder X-ray diffraction. Main research directions are the following: tautomeric interconversions in the solid state; intermolecular charge-transfer interactions and π-complexes; crystal packing effects on spatial and electronic molecular structure; crystallochromism, i.e. the difference in color of solid pigments due to molecular packing arrangements.

Contact: Alexandr V. Yatsenko (yatsenko@struct.chem.msu.su)

[1] Zhukov, S.G. et al. (2001). Z. Kristallogr. 216, 5-9. [2] Chernyshev, V.V. et al. (2001). Acta Cryst. C57, 982-984. [3] Chernyshev, V.V. et al. (2003). Acta Cryst. B59, 787-793. [4] Tafeenko, V.A. et al. (2003). Acta Cryst. C60, o62-o64.

Crystallography in Physics, Moscow State University

[physics staff at MSU] Staff of the Physics Department at Moscow State University..
A chair of X-ray structure analysis was created in 1932 as one of seven chairs in the Physics Department of Moscow State University. In 1953, it became the Chair of Solid State Physics. Department Chairs have included S.T. Konobeevsky, the first Chair, V.I. Iveronova (a winner of the Fedorov prize of Soviet Academy of Science), and M.M. Umansky (a winner of the Lomonosov Prize of Moscow State University).

The current chair, A.S. Ilyushin, is a leader in the field of education programs on condensed matter among Russian Universities. The program combines the teaching of experimental methods (X-ray, Mossbauer etc.) with basic principles of solid state physics (atomic, electronic and defect structures of crystals, dynamics of the crystal lattice, and phase transformations).

From the 1940s through the 70s a group under M.M. Umansky developed an experimental set for X-ray studies of crystal structure which also won a Lomonosov Prize (M.M. Umansky, S.S. Kvitka, and V.V. Zubenko). Recent research has included the development of new methods of X-ray and Mossbauer structure analysis of ideal and real crystals and application of these methods to studies of phase transformations and defects in metals, alloys, semiconductors and multi-layer films; evolution and self-organization of crystals and their electronic structure; and non-equilibrium phenomena and surface layers. Significant results have included:

a) A non-monotonic structural evolution, including a discrete (jump) evolution in the non-equilibrium metal-hydrogen systems was discovered, and a synergetic model was proposed (A.A. Katsnelson, G.P. Revkevich, and V.M. Avdyuhina).

b) An effect of internal magnetostriction in the rare-earth intermetallic compounds was found and its atomic-ionic mechanism was estimated (A.S. Ilyushin).

c) X-ray and Mossbauer diffraction near-edge spectroscopy of crystals and multi-layer films allowed depth-selective studies of atomic and magnetic structure (R.N. Kuzmin, V.A. Bushuev, M.A. Andreeva, and E.N. Ovchinnikova).

d) A wave theory was proposed for 3D internal structure reconstruction in low-absorption non-crystals based on phase-contrast X-ray refraction tomography, featuring orders of magnitude higher image contrast and 1-2 orders lower dose of absorbed radiation (V.A. Bushuev, patented method).

e) Molecular dynamics simulation and ab initio electronic structure calculations were used to study the formation of adsorbed nanostructures on metal surfaces and to predict the physical properties of surface layers (A.A. Katsnelson and V.S. Stepanyuk).
Contact: Albert A. Katsnelson (albert@sols3591.phys.msu.ru)

Crystallography and Crystal Chemistry of Geology, Lomonosov Moscow State University

[atomization energy] The atomization energy distribution in malayaite CaSnOSiO4.
The Department of Crystallography and Crystal Chemistry of Geology was founded in Lomonosov Moscow State University by G.B. Bokii in 1949. In 1961 N.V. Belov became the head of the department. From 1983 on the department has been headed by V.S. Urusov. Currently the staff consists of 25 teachers, researchers, and engineers. Since its founding, X-ray crystal structure determination of minerals and their synthetic analogues has been the major focus of the department. More than 200 new crystal structures of minerals have been solved. Another important field of activity for this group (Corresponding Members of RAS D.Yu. Puscharovsky, E.L. Belokoneva, O.V. Yakubovich, Yu.K. Egorov-Tismenko, N.A. Yamnova, and N.V. Zubkova) is mineral systematics and classification based on their structural characteristics, especially crystal chemistry of the main rock-forming minerals: silicates, phosphates, borates, etc.

[silicate] Silicate raite: X-rays from synchrotron source and its spherulite morphology.
In the past 2 decades precision X-ray diffraction studies and electron density distribution analysis in oxide and silicate minerals have also been conducted (V.S. Urusov, E.L. Belokoneva, O.V. Yakubovich, N.N. Eremin). Another group of scientists (Yu. K. Kabalov, N.V. Zubkova) is deeply involved in modern powder diffraction methods using Rietveld refinement of mineral crystal structures.

A central point in the domain of theoretical crystal chemistry is occupied by the development of energetic analysis of stability and properties of pure crystals and solid solutions. Recent activities of the group (V.S. Urusov, N.N. Eremin) have concentrated on the problem of computer modeling of structures and properties of mineral and inorganic solids using semi-empirical interatomic potentials as well as on the development of atomistic and phenomenological theory of isomorphous substitutions. Their original approach is minimization of crystal atomisation energy which accounts for the actual character of chemical bonds in crystals.

[staff after exam] The staff and students after the last exam.
In addition to crystal chemistry and X-ray diffraction groups, the department includes two laboratories doing single crystal growth: growth from high-T complex flux melts (N.I. Leonyuk, V.V. Maltsev) and growth from hydrothermal solutions (O.V. Dimitrova). Most crystals obtained in these laboratories possess technologically useful properties, e.g. lasers, fiber optics, ferroelectrics, high-T superconductors, superionic conductors, etc. Many have been the subjects of detailed crystal structure determination.

[titanite] Electron density in titanite CaTiOSiO4.
The department is responsible for the crystallographic education of all students (about 200 per year) of the Geological Faculty of Moscow State University as well as for the special education of bachelors, masters and PhD students in the field of crystallography and crystal chemistry (5-6 students and 3-4 post-graduate students per year). Courses include general crystallography, theory of symmetry (Yu. K. Egorov-Tismenko), introduction to crystal chemistry and advanced theoretical crystal chemistry (V.S. Urusov, N.N. Eremin), X-ray diffraction and crystal structure analysis (D.Yu. Puscharovsky, N.N. Zubkova), crystal morphology (G.I. Dorokhova), and crystal growth (N.N. Leonyuk, E.V. Koporulina).

[home-made crystals] Our self made crystals.
In recent years the following text-books (in Russian) have been published by the teachers in the department: 'Crystallography' (1992) by Yu. Egorov-Tismenko et al., 'Theory of crystal symmetry' (2000) by Yu. Egorov-Tismenko & G. Litvinskaya, 'Theoretical crystal chemistry' (1987) by V. Urusov, 'X-ray diffractometry' (2000) by D. Puscharovsky, 'Structural types of minerals' (1990) by D. Puscharovsky & V. Urusov, 'Design of probable crystal structures of minerals' by V. Urusov et al.
Contact: Vadim S. Urusov (crystal@geol.msu.ru)

Crystal Chemistry, Lomonosov Moscow State University (MSU)

[studies in crystal chemistry] Studies on crystal chemistry.
The laboratory was established in 1952 by G.B. Bokii, and first directed by M.A. Porai-Koshits. The current head of the laboratory is Peter M. Zorky and all students (200 to 250) of the department take the crystal chemistry course each year, which includes:
  • The history of the X-ray structural methods and of crystal chemistry;
  • Fundamentals of diffraction;
  • General principles of characterization and interpretation of crystal structures, including the theory of symmetry;
  • The thermodynamics of isostructurality, isomorphism, polymorphism, and morphotropy;
  • Systematic description of crystals and properties of metals, non-metals, binary and ternary compounds, silicates, coordinate compounds, organic substances;
  • The use of concepts from crystal chemistry and X-ray studies to characterize condensed phases with full and partial ordering: liquid crystals and liquids.

The study of crystal chemistry is not limited to crystallographic point and space groups, but has been expanded to include non-crystallographic axes and the symmetry of rods and slices.

A considerable portion of the course is dedicated to organic crystal chemistry and includes the following subjects: symmetry and structural classes of homo- and heteromolecular crystals; theory of close packing of molecules; calculation of the energy of intermolecular interaction in the atom-atom approximation; specific intermolecular contacts and their aggregation (hydrogen bonds, halogen-halogen contacts, and specific contacts involving benzene rings); and revelation of molecular aggregates in organic crystals; the influence of molecular aggregation on the properties of solid and liquid organic substances. The mastering of crystal chemistry requires visualization of structures (with the use of real ball-and-stick models, slides and animation).

[models] P.M. Zorky, A.E. Obodovskaya and student Anna Soloshenko showing models of crystal structures.
Since the 1970s theoretical studies in the field of organic crystal chemistry conducted under the direction of P. M. Zorky Crystal Chemistry, Lomonosov Moscow State University (MSU) have been a primary research focus. He has developed a topological classification system for organic crystal structures as ordinary, unordinary, and extraordinary, viewing molecular aggregation as optimal arrangements rather than molecular packing, and studied the coexistence of difficult conforms in the same crystal and the presence of common aggregate forms in difficult polymorphic hydrates or solvents. It is likely that the fragments of molecular aggregates that are present in crystals are retained in melts and in solutions, which is the cause of the microheterogeneity of liquid phases.

Correlations between the structures of liquids and crystals are another basis for generalization of crystal chemistry and the exploration of the interdependence of pharmacokinetical properties of drugs, crystal formation, and molecular aggregation in solution, computer simulation of the structures of solutions, and the interpretation of their melting temperatures, measurement of light scattering and of acoustic speeds in organic liquids and in their mixtures.

One of the most recent studies carried out in the laboratory of crystal chemistry is the refinement of the values of van der Waals radii of organogenic elements on the basis of the statistical treatment of structural data taken from 10000 crystal structures in the CSD.
Contact: Peter M. Zorky, (zorkii@cryst.chem.msu.su)

High-resolution protein structure at the Institute of Bioorganic Chemistry, RAS, Moscow

[LMC]LMC in December 2003: (left to right) Tatiana Petrova, Natalia Lunina, Vladimir Y. Lunin, and Tatiana Skovoroda.
[Institute]
Research directions include X-ray studies of structure function relations of enzymes, molecular aspects of protein-carbohydrate and antibody-antigen interactions.

The crystal structure determinations (resolution 2.1 Å) of a series of Ca++, Mn++ containing protein - pea lectin in complex with gluco- and mannopyronoside derivatives have revealed the stereochemical features of the binding site responsible for carbohydrate recognition and binding. Based on the determined structure, residue mutations were proposed to change carbohydrate specificity.

The three-dimensional structure (resolution 2.4 Å) of serine protease and bovine duodenase demonstrated the structural features of the active site compatible with effective accommodation of P1 residues typical of trypsin (Arg/Lys) and chymotrypsin (Tyr/Phe) substrates. These specificities in the past were considered to be mutually exclusive. The computer modeling of the complexes with the corresponding octapeptide substrates confirmed the experimental conclusions. The obtained results may permit design of enzymes with a specific ratio of trypsin and chymotrypsin activities.

The crystal structure of the Arg32His mutant of the human tumor necrosis factor (TNF-a), an important immune mediator, has been established at 2.5 Å. Models of the structure complexed with P55 and P75 receptors explained the decrease in its cytotoxic activity. The three dimensional structure of the antigen binding fragment of a monoclonal antibody to human interleukin-2 complexed with antigenic nonapeptide has been determined at 3 Å resolution. Antibody-antigen complexation involves a significant rearrangement of the epitope containing region of the interleukin-2 with retention of the α-helical character of the epitope fragment.
Contact: V.Z. Pletnev, (pletnev@ibch.ru)

Macromolecular crystallography in Pushchino

[electron density] Low resolution crystallographic image of a lipoprotein particle obtained in collaboration with the Medical University of Freiburg (Germany) and Universities of Nancy and Strasbourg (France).
The Institute of Mathematical Problems of Biology (IMBP) (www.impb.ru) was founded in the Pushchino Biological Centre of the Academy of Sciences in 1972 to create a link between mathematicians, computer scientists and biological laboratories interested in using mathematical and computer tools. A special program for development of protein crystallography was launched in 1976 that required huge computer support. The IMPB group spent its early years in close collaboration with the crystallographic laboratory (headed by Yu. Chirgadze) of the Institute of Protein Research (Pushchino), and benefitted from the advice of V. Borisov (Institute of Crystallography, Moscow). This era ended in the early 80's with the creation in Pushchino of a computational environment that supported all stages of macromolecular structure investigation, including model refinement (protein structure solution was not a routine procedure in those days).

Subsequently, the activities of the laboratory (see www.impb.ru/lmc for more details) have concentrated on development of new mathematical approaches and software for macromolecular crystallography, and collaboration with different laboratories on macromolecular structures. In particular, the laboratory has facilitated the use of the maximal likelihood principle in macromolecular crystallography (1982), the use of electron density histograms (1986) and the use of mixed (hybrid) electron density models (1984) for phase improvement etc. Most recently the main activity of the laboratory has concentrated on the development of ab-initio phasing methods suitable for low and middle resolution stages of crystallographic studies of macromolecular objects.
Contact: Vladimir Y. Lunin (lunin@impb.psn.ru)

Institute of Solid State Physics of the RAS

[panorama] Panorama ISSP RAS.
The ISSP RAS was founded in 1963 by George V. Kurdumov and Yurii A. Osipyan at the Research Center Chernogolovka in beautiful forests near Moscow. The focus of ISSP activities are: condensed-matter physics, materials science and new technologies. The Institute has laboratories for structural analysis by XRD and electron diffraction techniques. Microstructure investigations are carried out by the methods of X-ray spectroscopy, transmission electron microscopy (TEM), high-resolution transmission electron microscopy (HREM), scanning electron microscopy (SEM) and Mossbauer spectroscopy. Most of the facilities have low (liquid helium) and high (up to 2000oC) temperature capabilities. The staff includes five Doctors of Sciences, 12 PhD scientists, and 2-4 post-graduate students.

A variety of crystallographic problems are under investigation.

Crystallography of phase transformations and aperiodic crystals

[Fermi sphere] Brillouin zone - Fermi sphere.
[1d conductor] Crystal structure of 1D organic conductor (TSeT)3FeNO(CN)5].
[2d conductor] Crystal structure of 2D organic metal b”-(BEDT-TTF)4Rb[FeNO(CN)5]2.
Since 1930s the name of Kurdumov has been associated with non-diffusion (martensite) transformations in steels and 'shape memory' effect in alloys. Today these ideas open up a large and diverse field of experimental research. Transformations connected with the cooperative motion of atoms occur in many crystal families. Data on structural changes at temperatures down to 4.2 K, under mechanical loading, in electric fields, and under optical pumping have been obtained from metals, dielectrics, ferroelectrics, and HTSC materials. Experts in the laboratory have studied domain systems in A-15 alloys and in high-Tc compounds; the para-ferro-electric transitions in KDP and perovskite crystals; and transformations of polytypic systems of ZnS by oriented loading.

Another current focus is analysis of aperiodic crystals. The invar effect in incommensurate phases, i.e. the zero-coefficient of thermal broadening in the temperature region of the IC phase has been established. A new type of incommensurate composite structures has been discovered in (Rbx(NH4)(1-x))2SO4 crystals. These composites exhibit incommensurability of host and guest substructures along all three crystallographic directions. To define the structure and properties of such composites, we examine changes in the structures as a function of temperature, pressure and electrical field. A sequence of phase transitions from an incommensurate composite phase into commensurate ones has been detailed and we have shown that the oriented stress causes the phase transition in the host or guest structure.
Contact: V. Shekhtman, I. Shmytko (shekht@issp.ac.ru; shim@issp.ac.ru)

Structure analysis of high pressure phases

[diffraction patterns] X-ray diffraction patterns from amorphous (curve a) and nanocrystalline (curve b) structure with very small grain size.
The high-pressure X-ray diffraction group is engaged in the study of phase transitions in metallic alloys. A series of intermetallic phases was synthezied under pressure and crystal structures analyzed. The concept of Brillouin zone - Fermi sphere interactions is applied to account for phase stability in sp metals and alloys. Enhanced Hume-Rothery arguments under high pressure are shown to be responsible for structural complexity in 'simple' metals. For instance, the Li-cI16 phase [Hanfland et al. (2000) Nature 408, 174] is related to the classical Hume-Rothery phases with the Fermi surface close to the Brillouin zone boundaries.
Contact: Valentina F. Degtyareva (degtyar@issp.ac.ru)

Structure analysis of low-dimensional organic conductors

[HREM image] HREM image from amorphous.
The group, headed by R. Shibaeva, is studying the relationship between the crystal structures and physical properties of low-dimensional organic conductors. X-ray studies of organic radical cation salts with π-organic donors and various anions have been conducted. Compounds under investigation include semiconductors, organic metals with an M-I transition, stable organic metals and organic superconductors. The structural origin of first-order phase transitions are established, electronic band structures calculated, and theoretical and experimental electronic structures compared. Detected regularities in the structure of organic metals led to the development of some prescriptions for direct synthesis. Recently we have begun to study hybrid materials that combine π-electron donor networks, responsible for electronic conductivity, with counterion networks having distinct physical properties (magnetism, photochromism,etc.). Radical cation salts of organic π-donors with the photochromic metal mononitrosyl complexes and magnetic metal oxalates as counterions have also been studied.
Contact: R. Shibaeva, S. Khasanov, L. Zorina (shibaeva@issp.ac.ru)

Amorphous and nanocrystalline systems

Metal-metal and metal-metalloid systems in amorphous and nanocrystalline states are being studied by X-ray diffraction and transmission and high resolution electron microscopy. Samples are produced by controlled crystallization of metallic glasses. Structure stability and evolution have been studied in Fe-, Co-, Ni-, Pd-, Al-, Mg-, Cu-, Zr-based alloys after the decomposition of amorphous alloys prepared by melt quenching. The Al-Ge, Zn-Sb systems were investigated under crystallization of an amorphous phase produced by high pressure with subsequent quenching to liquid nitrogen temperature. The grain size of the nanocrystals is 5-20 nm and the X-ray diffraction pattern contains broadened reflections for small nanocrystals (about 1-5 nm) the X-ray diffraction pattern (Figure below, curve b) is close to that of an amorphous phase (curve a). Both diffraction patterns contain only diffuse maxima, but the curves are different. Curve b corresponds to the structure consisting of both the amorphous phase and nanocrystals with the grain size of 1-5 nm. The high resolution electron microscopy image of this structure is shown in the figure. The structure contains a lot of very small nanocrystals. Analysis of the angular dependence of the diffraction line halfwidth allows us to estimate the main contribution to the broadening and draw conclusions about the fine structure of nanocrystals. All nanocrystals have been found to be defect-free, while Ni nanocrystals contain stacking faults, dislocations, microtwins etc.

Contacts: A. Aronin (aronin@issp.ac.ru), G. Abrosimova (gea@issp.ac.ru)

X-ray optics of real crystals

X-ray optical diffraction effects under investigation include diffraction focusing of X-ray Bloch waves in perfect single crystals, dynamic diffraction on bent single crystals, waveguide and channeling effects, and X-ray interferometry in a continuous radiation spectrum. Short-wave hard radiation scattering in a short-range field of deformation has been studied, schemes of focusing X-ray optical elements have been proposed, and specific features of diffraction in disordered quasi-crystals have been investigated. A software package has been written to interpret and simulate diffraction images obtained by Laue, Debye and rolling-crystal methods. The phase velocity of hard electromagnetic radiation in a medium is higher than the velocity of light in vacuum. Therefore the effects of both total external and total internal reflections exist for X-ray waves. Experiments on X-ray dynamic diffraction in limited perfect single crystals have been carried out under the conditions of total internal reflection of a scattered wave from a crystal-vacuum interface. The interference pattern, formed by a sum of the primary and mirror-like reflected scattered waves, is extremely sensitive to weak distortions of the crystal lattice. The results obtained open new prospects for diagnostics of defects in single crystals and development of new elements for X-ray optics.

Contact: Ernest Suvorov, Irina Smirnova, Evgeniy Shulakov (suvorov@issp.ac.ru)

Leonid A. Aslanov

[Leonid Aslanov]Leonid A. Aslanov was born in St. Petersburg, Russia in 1938 and studied chemistry at Lomonosov Moscow State University. After graduating from the University in 1960 he pursued his interest in crystallography and received his PhD in 1963 based on his studies of the synthesis and crystal structure determinations of ternary sulphides and selenides of alkali earth and some d-transition metals using powder diffraction. He is now employed by the Department of Chemistry of Moscow State University where he started as a junior researcher and is now a full professor.

Between 1965 and 1973 he investigated crystal structures of coordination compounds of rare earth elements and developed, in collaboration with M.A. Poraj-Koshits, a principle for determination of eight-vertexes polyhedra that has had broad application. (J. Struct. Chem. 13, 244 (1972)).

From 1973 to 1987 his research centered on the synthesis and crystal structure determinations of coordination compounds of tin, lead, and antimony and he found, in collaboration with V.S. Petrosyan and O.A. Reutov, a phenomenon of the trans-strengthening of bonds in octahedral complexes of tin and lead which is opposite to trans-effect in transition metal complexes (Zh. Strukt. Khim. 29, 112 (1089)).

From 1979 to 1992 he developed crystal chemical models of atomic interactions (Acta Cryst. B44, 449 and 458 (1988), A45, 661 and 671 (1989), A47, 63 (1991), A48, 281 (1992)). During this period (1981 to 1991) he started an exploration of photocrystallography and together with his collaborators built a specialized four-circle diffractometer (J. Appl. Cryst. 22, 42(1989)), developed software (J. Appl. Cryst. 24, 293 and 910 (1991)) and performed investigations on ferroelectric materials (J. Appl. Cryst. 23, FC1 (1990)). This research was stopped due to lack of financial support in 1992.

Since 1992 he has been doing research in materials science. During the period betwen 1992 and 1998 he proposed, and tested experimentally, an optoacoustic mechanism of latent image formation in silver halide materials (Laser Physics 6,1105 (1996)). Since 1999 he has been studying the crystallization of nanoclusters in ionic liquids.

L.A. Aslanov did postdoctoral research during the 1967-1968 academic year at the University of Sheffield, UK under the supervision of Ronald Mason. He had a Kapitsa Fellowship in 1993 with Judith A.K. Howard at the University of Durham, UK and from 1992 to 2003 he collaborated in the framework of NWO-grants with Henk Shenk at the University of Amsterdam.

L.A. Aslanov is now Vice-President of IUCr, Co-Editor of Acta Crystallographica A, B, C, D, Zeitschrift für Kristallographie and Associate Editor of Crystallography Reviews in addition to activities with other Russian journals and organizations. He has published over 300 papers, 6 books on crystallographic instrumentation, X-ray diffraction, crystal chemistry and another, on ionic liquids, is now in print. He has directed 28 PhD theses.

Hopefully, the articles on 'Crystallography in Russia' presented in this issue of the IUCr Newsletter have begun to provide an accurate picture of crystallography in modern Russia. With these articles, and those to come in the next issue, we will have demonstrated various branches of crystallography: X-ray, synchrotron, neutron instrumentation and methods; development of methods for crystal structure determination based on powder diffraction data; charge density; minerals, small molecules, proteins, aperiodic structures and amorphous materials; crystal growth; crystalline films; high pressure crystallography; Voronoi-Derichlet polyhedra; teaching crystallography and so on and so forth. All comments and remarks should be sent to

L.A. Aslanov, Dept. of Chemistry, Moscow State U., 119992 Moscow, Russia; aslanov@struct.chem.msu.ru.

 

Crystallography in Russia

Part 2

Kirensky Institute of Physics

[Kirensky Institute of Physics] Kirensky Institute of Physics (main building) – Siberian winter.
Investigations of crystal physics and development of their applications are the main activities of the Kirensky Institute of Physics (Krasnoyarsk). Researchers at the institute study piezoelectrics, ferroelectrics, ferroelastics, and magnetic dielectric crystals, and crystals containing rare earth ions for optical applications.

[garnet crystals] Garnet crystals – as grown by group flux-melt method.
Methods of group flux melt growth developed here provide a means to obtain high quality bulk crystals of copper-germanium oxide, lead gallium germanate, and copper metaborate under controlled conditions. Neodymium-activated crystals of gadolinium-gallium garnets synthesized by this method appear to be a single-center medium with more than 10 at.% of Nd3+.

Searching for new crystals demands systematic analysis of known structures to provide a foundation for a reliable prognosis. Such analysis has been performed for oxide- and halogen-based perovskites, antiperovskites, elpasolites, anion- and cation-deficient and layered perovskite-like structures, including high temperature superconductors. Group-theory and crystallographic analyses of phase transitions in these structural families have been made as well.

Structures of synthesized crystals are investigated using powder and single crystal X-ray analysis. Neutron scattering data are used in collaboration with the Joint Institute of Nuclear Research (Dubna, Russia), the Hahn-Meitner Institute in Germany and the Laboratoire Leon Brillouin at the Saclay Neutron Center in France.

[A.D.Vasiliev] A. D. Vasiliev at single crystal X-ray diffractometer – deciphering a structure of a new crystal.
Fundamental goals are to correlate physical properties of materials with their crystal structures and to determine the impact of external forces on crystal parameters and phase transitions. Physical properties studied include electric and magnetic parameters, acoustic and optics measurements, heat capacity and thermal expansion. With Krasnoyarsk State University, nonlinear electro mechanic properties higher order elastic coefficients, electrostriction, and nonlinear piezoeffects are studied. A study of β-K2SO4 crystals revealed a complex sequence of phase transitions that include disordered and incommensurate phases. Radio spectroscopic and optical second harmonics investigations of incommensurate phases are conducted. The concept of solution density measurements by NMR analysis was formulated here and Raman scattering selection rules for these phases have been developed and experimentally tested. Recent investigations have focused on complex phase transitions of halogenides and oxyhalogenides with perovskite-like structures including structurally disordered ferroelectric-relaxors.

A theory of structural phase transitions is being developed in parallel with experimental investigations. Phase transition sequences with interacting order parameters are developed based on group theory and thermodynamics and applied to families of crystals. Attention is focused on model descriptions of these phase transition sequences. Ab initio approaches are being developed that describe the stability, lattice dynamics and physical properties for complex crystal structures like layered perovskites and elpasolites.

In 1976 the Krasnoyarsk School of Crystal Physics began a series of Soviet (now - Russian) - Japanese symposia on the physics of ferroelectrics that continues to the present day.

Contact: K.S. Aleksandrov kaleks@iph.krasn.ru

Material studies in Petrozavodsk

At the X-ray laboratory of the Petrozavodsk State University, amorphous oxide films, amorphous and crystalline powders and bulk materials are studied. X-ray diffraction patterns from symmetric and asymmetric reflection and transmission geometry are obtained on a DRON-4 diffractometer using monochromatized radiation of various wavelengths.

The short-range order characteristics of amorphous, amorphous-crystalline and small dispersion materials are defined using the Finbak-Warren approach: the D(r) curves are presented as a sum of pair functions. We have identified the short-range order characteristics of amorphous oxide films of aluminum, silicon, tantalum, niobium, tungsten, yttrium, and vanadium, produced under different conditions of anode oxidation; WO3 films, thermally evaporated in vacuum; silicon films, produced by monosilane pyrolysis at various temperatures; thermal silicon dioxide films; and manganese dioxide produced by pyrolysis of manganese dihydrate. Computer simulations of the structures of amorphous materials are calculated using the methods of continuous static relaxation, molecular dynamics, and non-ordering networks.

Octahedrally and tetrahedrally coordinated cations with distorted fcc packing of oxygen atoms in the system 'aluminum-vacant cationic positions' were considered in terms of short-range order coefficients. The cationic subsystem of amorphous aluminum oxides is characterized by a short-range order qualitatively analogous to the arrangement of aluminum atoms in the boehmite and pseudoboehmite modifications of the γ-Al2O3 phase. The correlation length in the system 'aluminum-vacant cationic positions' is not less than 5 Å. It was shown that the short-range order in amorphous oxide films of Ta2O5 and Nb2O5 can be regarded as similar to the atom positions in the crystal modifications β-Ta2O5 and γ-Nb2O5. The X-ray study and molecular dynamic computer simulation of amorphous anodic tungsten oxide showed that the arrangement of W and O atoms in the coordination spheres corresponds to the characteristics of the crystalline WO3·(1/3)2 modification. WO3 films, thermally vaporized-on in vacuum, have a quasi-amorphous structure characterized by the presence of crystallites shaped like orthorhombic phase parallelepipeds with dimensions 15 x 8 x 20 Å.

The short-range order in amorphous oxide films and powder of Y2O3 depends on anode oxidation conditions. Moreover, the first coordination number changes from 5 in colored oxides to 7 in black and powdered oxides. The short-range order is described in terms of models of disordered networks of octahedra, pyramids, and structural units, consisting of seven oxygen atoms. In amorphous fulleride C60 short-range order corresponds to the lonsdeillite crystalline phase. The main publications describing this work are in Crystallography Reports and Acta Crystallographica.

Contact: Lioudmila A. Aleshina alkftt@mail.ru

Crystallography in Novosibirsk

[crystallography in Novosibirsk]

Almost 1.5 million people live in Novosibirsk, more than 30 000 are involved in the work of the Novosibirsk Scientific Center. Novosibirsk State University is surrounded by about 40 research institutes of the Russian Academy of Science. Integration of the Novosibirsk State University with the Russian Academy of Sciences was always exceptionally high for Russia. Crystallography is widely applied in many institutes, ranging from traditional applications in chemistry, physics, biology, and ending with archeology. Novosibirsk is a huge high technology industrial center with vast potential for studies with broad applications.

[summer school] Summer schools attract participants of all ages.
[H. Ahsbahs] H. Ahsbahs from Philipps University (Marburg/Lahn, Germany) and A. Achkasov from Novosibirsk State University discuss some technical details of a high-pressure experiment.
[J. Lipkowski] J. Lipkowski of Poland gives a lecture on crystallography and physical chemistry of inclusion compounds.
[Stoe diffractometer] A single crystal diffractometer STADI-4 (STOE, Darmstadt) was specially adapted on the request of the group for high-pressure data collection.
[GADDS diffractometer] GADDS D8 diffractometer with a 2D-detector (Bruker, Karlsruhe) enables a rapid data collection from various samples – ranging from very small amounts of powder samples to pieces of ceramics and rocks.
[calorimetry] Thermal analysis and calorimetry – TG, DSC, TMA - (NETZSCH, Selb) are important techniques complementary to X-ray diffraction.

Solid state chemistry and mechanochemistry

The group of Elena Boldyreva divides its activities between the Institute of Solid State Chemistry and Mechanochemistry (Siberian RAS, Novosibirsk) and the Novosibirsk State University.

Research

Boldyreva is a physical chemist who specializes in studies involving solid-state kinetics, inorganic solids, coordination compounds, and organic molecular solids with a special emphasis on pharmaceutical and biomimetic systems. Fields of research include solid-state reactivity, crystal engineering, polymorphism, crystallographic computing, database analysis, high-pressure and low-temperature crystallography using single-crystal and powder X-ray structure analysis, systems studied include Co(III)-ammine complexes and polymorphs of paracetamol, glycine, serine, hexafluorosilicates, benzoquinone, and sodium oxalate. The effect of high pressure on a solid has been systematically compared with that of cooling. Diffraction studies are complemented by IR- and Raman spectroscopy, thermal analysis and calorimetry, and optical microscopy. The group collaborates with other research teams studying mechanochemical synthesis and mechanochemical modification of pharmaceuticals. They also work with colleagues from the Institute of Mineralogy, the Institute of Catalysis, the Institute of Semiconductor Physics, the Institute of Genetics, and the Institute of Archeology in Novosibirsk. With the latter, they have characterized samples of ancient Siberian ceramics. The group is actively involved in research in a multidisciplinary Research and Education Center REC-008 'Molecular Design and Ecologically Safe Technologies', and in the Center of Joint Exploitation of Equipment 'Integration'.

Education

The group is active in teaching solid state chemistry, crystallography, structural analysis and supramolecular chemistry at Novosibirsk State University. All chemistry students at the university attend the courses. Former students work at various research institutes of the Russian Academy of Sciences, in industry and abroad. In recent years the group has included PhD students and post-docs from Barnaul, Tomsk, Kemerovo, and Petrozavodsk. The teaching activities of the group were described in articles in the Journal of Chemical Education [J. Chem. Educ, 1993, 70(7), 551-556 and 2000, 77(2), 222-226]. E. Boldyreva, a lecturer at international schools, has translated E. Wood's 'Crystals' and 'Supramolecular chemistry' by J.-M. Lehn into Russian. In 2000 the group initiated a series of Novosibirsk summer and winter schools on 'Hot Topics of Chemistry, Biology, and Physics', which are attended by schoolchildren and teachers from all over Siberia. The group is an active member of the SigmaXi International Research Society and participates in the 'Distinguished Lecturers' program.

International collaborations

Boldyreva has been a visiting research scientist in Germany, France, Italy, and Great Britain. Many of her former hosts and 'western colleagues' have visited Novosibirsk, to lecture, exchange ideas, and test equipment. The group has traditional collaborations in Europe, good contacts in the USA, and has recently signed an Agreement for Cooperation with Wits-University (Johannesburg, South Africa).

Contact: Elena V. Boldyreva (boldyrev@nsu.ru)

in vivo X-ray diffraction analysis of cystic calculus

The potential to use synchrotron radiation for medical diagnosis via in vitro X-ray diffraction is being explored at the Synchrotron Center of the Institute of Nuclear Physics in Novosibirsk.

[Fig. 1] Figure 1.
[Fig. 2] Figure 2.
Urologists remove cystic calculi via lithoclasty without an abdominal operation, and fragments of calculi are excreted through the urinary tract. Analysis of the collected biominerals permits determination of a specific form of urolithiasis, which can guide therapy and prevent recurrence. These methods analyze cystic calculi only after their removal. It would be helpful to determine the composition of a crystal calculi without surgery.

We have attempted to model in vivo X-ray diffraction analysis of a cystic calculus. A surgically obtained calculus (5 x 3 x 3 mm) was placed into pig tissue with a high fat content. The investigation was carried out with quanta in the range 30-34 keV at an X-ray diffraction station[1] installed at the 4th synchrotron radiation beamline of the VEPP-3 storage ring in the Synchrotron Center.

First, a diffraction pattern of the cystic calculus was obtained. Then, the calculus was placed into the model fatty tissue and a new diffraction pattern was recorded. An example of a diffraction pattern from a cystic calculus in fatty tissue is shown in Fig. 1. Fig. 2 illustrates a comparison between the calculus embedding in fatty tissue (top) and the pattern for a sample of monohydrate calcium oxalate (bottom).

Such an investigation does not require a detailed analysis of the diffraction pattern, because most of the calculi are of three main types (oxalates, phosphates and urates). The diffractograms of these types differ sharply and identification of a calculus can be made with the signal/noise ratio as low as ~10. This method of recording the diffractograms does not require precise positioning of the sample.

As shown in Fig. 2, the type of the calculus can be determined from such data. These experiments demonstrate the feasibility of collecting the diffraction pattern of a cystic calculus embedded in fatty tissue. Although current radiation doses required for in vivo analysis exceed permissible levels, the development of more sensitive detectors could make the technique feasible.

[1] Ancharov A.I. et al., 'New station at the 4th beamline of the VEPP-3 storage ring' Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 470 (2001), 1-2, P.80-83

Contact: B. P. Tolochko (b.p.tolochko@inp.nsk.su)

Superconducting wigglers and shifters

[photon flux] Photon flux from the usual 1.5 Tesla bending magnet and 3.5 Tesla 49-pole superconducting wiggler for ELETTRA storage ring (2 GeV and 200 mA).
[shifter] 7.5 Tesla 3 pole shifter installed at the BESSY storage ring.
Budker INP at the Institute of Nuclear Physics, Novosibirsk has significant experience in the development and construction of superconducting insertion devices (ID). The first superconducting 20 pole wiggler was assembled in 1979 for the VEPP-3 storage ring. During the last 10 years, new types of superconducting wigglers and shifters for a number of storage rings around the world have been constructed. Strong field wigglers or wavelength shifters are installed in the straight section of the storage ring to enhance the performance of the machine for short wavelength users and to provide new possibilities for SR experiments. Reasons to install wigglers or shifters on a storage ring include: (1) to shift the spectrum to the hard X-ray region by using the higher magnetic field of the wiggler (shifter); (2) to increase the photon flux due to many poles (multipole wiggler); (3) to obtain new features of radiation such as polarization; (4) to obtain flexibility for experiments due to the possibility of changing the wiggler field during the experiment; (5) to decrease or increase the emission of the storage ring; (6) to decrease the polarization time of the electron (positron) beam; and (7) to create a slow positron source of high brightness. Generally a wiggler or shifter consists of a magnetic system, a cryogenic system, a vacuum system, a control system and power supplies.

Contacts: B.P. Tolochko B.P.Tolochko@inp.nsk.su

Inorganic crystallography

[phase transition] OD-3 measurement: The phase transition in MgZnAl.
[OD3 measurements] OD-3 measurement: behavior of mixture 0.7NiO + 0.3WO3 at 720oC.
The Crystal Chemistry Laboratory, established in the Siberia Nikolaev Institute of Inorganic Chemistry, SB RAS / Crystal Chemistry Laboratory in 1958 by Prof. G. Bokii (1909-2001), is the oldest and largest crystallography center in Siberia. The laboratory staff consists of 16 researchers, several engineers and students involved in X-ray structural and crystallochemical studies. The laboratory is equipped with powder and single crystal X-ray diffractometers. Research at the laboratory includes studies of inorganic and coordination compounds (S. Borisov, N. Podberezskaya, and S. Solodovnikov); transition metal coordination compounds including molecular magnetic materials and volatile complexes (N. Pervukhina, I. Baidina, S. Gromilov, L. Glinskaya, V. Alekseev, and T. Polyanskaya); complex oxides including molybdates, tungstates, hypo-phosphites, chlorites, natural and modified zeolites (R. Klevtsova, S. Solodovnikov, D. Naumov, and V. Bakakin); transition metal and boron cluster compounds (A. Virovets; S. Solodovnikov, T. Polyanskaya, and D. Naumov); mercury-containing minerals and their analogs (S. Magarill and N. Pervukhina); and supramolecular compounds containing transition metal complexes and cucurbit[n]urils (A. Virovets and N. Pervukhina).

High-quality powder patterns of bulk materials and films prepared in the institute (S. Gromilov) have been provided for the ICDD Grant-in-Aid Program (V. Lisoivan). Software that includes searches for cation sublattices and cavities, comparison and visualization of structures has been written (D. Naumov).

The laboratory produces about 100 crystal structures and 50 publications per year. Interesting recent results include:
  • The structure-forming role of cations in some classes of inorganic compounds that results in regular close-packed cationic arrays;
  • The structure-forming role of Hg-O, Hg-S, and Hg-Hg covalent bonds that results in the formation of rigid mixed mercury-anion clusters, ribbons, layers and 3D frameworks in inorganic mercury-containing compounds;
  • Algorithms for generating 3D tetrahedral clathrate frameworks using the duality of polyhedral clathrate hydrates and intermetallic structures.
The laboratory takes an active role in the education process of students in the Chemistry Department of Novosibirsk State University and cooperates with colleagues from Russia, Germany, UK, and Spain.

Contact: Sergey Gromilov, grom@che.nsk.su

Helically polarized radiation sources development in Budker INP, Novosibirsk
In recent years Budker INP has designed and manufactured several insertion devices for the generation of helically polarized radiation.

[undulator]
General view of one of two halves of elliptical electromagnetic undulator for advanced SR source SLS (Switzerland).

Contact: B. P. Tolochko (b.p.tolochko@inp.nsk.su)

Advanced X-ray detectors, INP

[OD3 supermodule] OD-3 electronics super-module with shapers, FLASH ADC’s, Processor Unit and RAM.
A fast, parallax-free, one coordinate detector OD-3 has been designed for angular measurements in diffraction experiments on a synchrotron X-ray beam with a photon energy around 10 keV within an angular aperture of 30 degrees. The OD-3 detector consists of a proportional chamber, CAMAC crate with electronics and a host IBM PC compatible computer. The proportional chamber of the OD-3 has a drift volume where the coordinate of quantum along the anode wire is detected by measuring the charge induced on the strips of the lower cathode plane. A peculiar shape of cathode strips 'focused' on the object under study provides parallax elimination. The design of the detector allows the minimum focus distance to be 350 mm with conventional ones of 350 mm and 1.5 meters. Events are stored in the Incremental RAM (256K x 32) in the Processor Unit and can be read into the computer for processing, visualization, and long-term storage.

Main parameters of the OD-3 detector
inlet beryllium window 200 mm x 10mm x 0.2mm
conventional operational gas mixture Ar/10% CO2
excessive pressure in gas chamber 0.2 atm
photon energy range 5-15 keV
detection efficiency (for 8 keV photons) 30 %
maximum detection angle ± 15 degrees at the focal distance 350 mm, ± 3.5 degrees at the focal distance 1.5 meter
scale 3328 channels
channel width 60 μm (0.01 degree at f = 350 mm)
maximum number of frames 1024 frames
frame time range 1 μs / 1024 seconds
space resolution (Eγ = 8 keV, STP), FWHM 150 μu;m (0.025 degree at f = 350 mm)
linearity 0.15 %
differential nonuniformity, R.M.S. < 2.5 %
counting rate (at 50 % non-efficiency)10 MHz/detector

Contact: B.P. Tolochko, B.P.Tolochko@inp.nsk.su

The structure of quantum dots by XAFS

[Ge nanocluster] Fig. 1. Circuit of Ge nanocluster (QD) on Si(001).
[Fourier transform] Fig. 2. Fourier transform magnitude of k3χ(k) GeK EXAFS data at E||Si(001): for pseudomorphous 4-monolayer (4ML) 2D- films on Si(001) – curve 1, for Ge nanoclusters on pseudomorphous 4-monolayer films on Si(001) with effective thickness equal to 6ML – curve 2, equal to 8ML – curve 3, equal to 10ML – curve 4.
Surface sensitive EXAFS- (Extended X-ray Absorption Fine Structure) and XANFS- (X-ray Absorption Near Edge Structure) techniques are used at the Nikolaev Institute of Inorganic Chemistry, Institute of Semiconductors Physics and Budker INP SB RAS, Novosibirsk to determine the spatial and electronic properties of heterogeneous surfaces[1,2]. Uniform germanium nanoislands deposited on Si(001) and Si(111) substrates via molecular beam epitaxy (MBE) (Fig.1) exhibit quantum dot (QD) properties. The influences of effective thickness of the Ge film, Ge nanocluster sizes and deposition temperature on the QD microstructure parameters were determined by EXAFS and XANFS techniques. The effective thickness varied from two to ten monolayers for the films studied. Two-dimensional pseudomorphous Ge films have been grown up to a critical thickness of four monolayers on Si(001). As a result of continuing deposition, pyramid-like Ge islands were grown in the Stranski-Krastanov mode. Local microstructure parameters are linked to nanostructure morphology and models are proposed. The Ge islands that form during growth are characterized by interatomic Ge-Ge distances of 2.41 Å (0.04 Å less than in bulk Ge). Pure Ge nanoclusters are covered by a 1-2 monolayer film with an admixture on the average of 50 % Si-impurity due to interface diffusion from blocking Si layers at 500°C. The monotonic size of germanium nanoclusters were determined as a function of film thickness and the influence of temperature change was measured.That microstructural parameters of Ge/Si heterosystems are largely influenced by elastic deformation at the boundaries due to a mismatch of lattice parameters of the nanocluster and substrate was detected by direct measurement showing that EXAFS spectroscopy is a useful tool for the study of materials containing nanostructures.

[1] Erenburg, S.B., Bausk, N.V., Stepina, N.P., Nikiforov, A.I., Nenashev, A.V., and Mazalov, L.N., Nucl. Instr. & Meth. Phys. Res. A. (2001) 470/1-2, 283-289. [2] Erenburg, S., Bausk, N., Mazalov, L., Nikiforov, A, and Yakimov, A., J. Synchrotron Rad. (2003), 10, 380-383.

Contact: B. P. Tolochko, B.P.Tolochko@inp.nsk.su

Nanoparticles nucleation under extreme conditions

[SAXS experiment] The experimental scheme for in situ SAXS investigation of shock wave impact on various materials.
Production of materials with new properties can be achieved via synthesis under high temperatures, high pressures and nonequilibrium conditions. To collect data under these conditions, equipment with nanosecond time resolution, high sensitivity to phases at low concentrations and high penetrating depth (millimeters) should be used. Synchrotron radiation has the required characteristics.

[time dependence] The time dependence of small angle X-ray scattering during diamond nanoparticle nucleation and growth under shock wave compression. Time t = 1 μs corresponds to room temperature and pressure, time t = 1.5-3.5μs – to high temperature and pressure.
For generating high temperatures and pressures we use explosions and shock waves. During the explosions in our experiments pressures can reach 2 Mbar with temperatures up to 8000° C. We have developed an 'extreme conditions' synchrotron radiation beamline which allows us to investigate the dynamics of phase transformations during explosion and shock wave impact. In particular we have investigated nucleation and growth of diamond and metallic particles by small angle X-ray scattering (SAXS). We have observed nuclei with sizes near 30 (at t=1.5 μs) and dynamic of growth up to 70 during 2 μs. The influence of different conditions on kinetics of nanoparticles growth have also been investigated.

[1] B.P. Tolochko, N.Z. Lyakhov et al. NIMA, v. 467-468, Part 2, 2001, p. 990.

Contact: B.P. Tolochko, B.P.Tolochko@inp.nsk.su

An X-ray detector for imaging explosions

[design of the detector] Figure 1. Design of the detector.
[explosion] Figure 2. Projective image of an explosion. Vertical scale is time in units of 500ns. Horizontal scale is position in 0.1mm channels.
Very short pulses of synchrotron light irradiated by individual electron bunches allow imaging of the development of a detonation wave and the changes of electron density within a volume of exploding materials. Such experiments require an exceptional set of parameters from the detector. In order to view independent images from different electron bunches, time resolution of the detector has to be less than bunch crossing time. A new detector for imaging fast dynamic processes and explosions with SR beam (DIMEX) was constructed in Budker Institute of Nuclear Physics. Details of the instruments construction are reported in the references below. In order to investigate the structure and velocity of a detonation wave in an explosion, as well as density distribution inside and around the exploding sample, the projective absorption experiments were conducted using DIMEX. The collimated line-shaped beam passed through the sample and the distribution of X-ray flux was measured. Our beam was ~12 mm wide and 1mm high. The samples were 12.5 mm in diameter and 100 mm cylinders made of a mixture of hexogen and TNT. The sample was positioned with its axis either parallel or perpendicular to the beam plane. The start of the measurement sequence could be synchronized with the detonation to within ~0.5s. A sequence of small angle scattering (SAXS) images give information about the concentration of particles with different dimensions in an object. The result of a series of projective absorption experiments is shown in Fig. 2. In order to improve the precision, the results of 10 measurements were summed with proper synchronization. The horizontal axis of the figure is the position perpendicular to the axis of the sample. Time axis is in vertical in units of 500 ns. The figure shows the detonation wave and the reaction zone with very high density just after the detonation front. The technique of very fast imaging opens opportunities in an area of fast dynamic SAXS and WAXS (wide-angle X-ray scattering) studies of an objects under the influence of either different external factors like temperature, pressure, light etc., or internal meta-stable or excited states.

[1] A.N. Aleshaev et al., Nucl. Instr.and Meth. A470 (2001), 240.
[2] B.P. Tolochko et al., Nucl. Instr.and Meth. A467-468 (2001), 990.

Contact: L. Shekhtman (lshekhtm@inp.nsk.su)

International Tomography Center

[display]
[framework]The projection of a framework [Mn6(O)2(Me3C2O2)10(L)2]; R-3c, a = 27.476(4), b = 27.476(4), c = 66.576(8)Å, V = 43526(10) Å3.
Current research at the International Tomography Center of the Siberian Branch of the Russian Academy of Science (ITC SB RAS) in Academgorodok, Novosibirsk) is centered on designing molecular magnets. This work involves the synthesis of solid organic, metalloorganic or coordination compounds that are formed from molecules or ions containing paramagnetic centers (i.e. molecules or ions having unpaired electrons) and for which a magnetic phase transition in the magnetic-ordering state can be determined. The current state-of-the-art in synthetic chemistry allows one to produce solid compounds with desired structural features starting from molecular precursors in solution. Crystals grown from these solutions can be designed to form chained, layered or frame polymers. However, to produce a magnetic phase transition in a ferromagnetic state not only the formation of layered or frame structures is required, but the presence of effective exchange channels between the paramagnetic centers is also necessary. Understanding the molecular and crystal structure of magnets allows the elucidation of the system of exchange clusters in solids and reveals magneto-structural correlations; the interrelation between the structure of a paramagnetic ligand, its coordination, the nature of the central atom, the character of molecular packing, and magnetic properties. In some cases a series of X-ray diffraction experiments covering a wide range of temperatures is necessary to identify the structural changes occurring in solids of coordination compounds leading to a change in magnetic properties. At the ITC SB, X-ray diffraction studies of stable nitroxides and heterospin nitroxide-containing coordination compounds have been performed. The discovery of so-called 'breathing' crystals is the most significant result in recent years. 'Breathing' crystals are a group of Cu (II) hexafluoroacetylacetonate complexes with spin-labeled pyrazoles LR (R = Me, Et, Pr, Bu) - Cu(hfac)2LR, having a chain polymer structure with a 'head-to-head' or 'head-to-tail' motif that results in bridging coordination of LR through the N atom of pyrazole and the O atom of the nitroxide group. These complexes are characterized by a reversible magnetic phase transition and a 10% compression of a unit cell up to 300 Å in absolute value. As temperature is lowered single crystals retain the quality necessary for X-ray diffraction, despite the occurrence of a structural phase transition. This allowed us to study compounds at different temperatures and to reveal the most important components of structural dynamics. Phase transition manifests itself in a sharp change in the coordination polyhedron of Cu(II). Also, weak ferromagnetic properties of Cu (II)-O•-N< clusters can be exchanged for strong antiferromagnetic ones. X-ray diffraction studies over a wide temperature range as well as investigations of crystal structures with long unit cell parameters became possible due to the acquisition of a Smart Apex (Bruker AXS) CCD diffractometer. Currently more than 300 structures per year are determined in ITC SB RAS.

Contacts: Dr. Galina Romanenko tev@tomo.nsc.ru

Neutron diffraction in Russia

[experimental hall] Figure 1. Experimental hall of the IVV-2M reactor with neutron spectrometers of the 'Neutron investigations of condensed matter' centre, Institute of Metal Physics (Yekaterinburg).
[temperature dependence] Figure 2. The behavior of Tc vs. extra oxygen or fluorine content in HgBa2CuO4(O,F)δ. Compounds with extra oxygen (O2−) content δ≈0.12 and extra fluorine (F1−) content δ≈0.24 demonstrate the same maximal Tc≈98 K.
[bond distances] Fig. 3. Bond distances Hg-O2 (left scale, open symbols) and Cu-O2 (right scale, full symbols) as a function of extra oxygen or fluorine content. In both compounds with oxygen content δ≈0.12 and fluorine content δ≈0.24, Tc≈97 K.
[bond lengths] Figure 4. Comparison of the temperature dependencies of the average <Mn-O> bond length (at the bottom) and the average <Mn-O-N> valence angle (at the top) for two (La0.25Pr0.75)0.7Ca0.3MnO3 compounds with oxygen isotopes 16O (Ο-16) and 18O (Ο-18). The arrow indicates the temperature of the Ο-16 sample transition into the ferromagnetic state.
[diffraction pattern] Figure 5. Diffraction pattern of the La2CuO4.04 single crystal measured at 10 K with HRFD. Figures denote the reflection orders. Each line is split, as shown for 12th order in the insert, due to crystal phase separation on the oxygen rich and oxygen poor phases.
[heavy ice] Figure 6. Phase transformations of high pressure heavy ice VIII, studied by neutron diffraction at DN-2 instrument. At the beginning time/temperature scale T=94 K, at the end T=275 K. The heating rate was ≈1 deg/min. Diffraction patterns have been measured each 5 min. Phase VIII is transformed into cubic phase Ic and then into hexagonal ice Ih.
Use of neutron diffraction for crystal structural investigations began in Russia in the early 1960s. The IBR reactor in the Joint Institute for Nuclear Research (JINR) (Dubna, Moscow Region) was the site of many scientific achievements, including the first pulsed neutron source in the world where time-of-flight methods were used for crystallographic experiments. At present neutron diffraction studies of atomic and magnetic structures in Russia are carried out at 4 large scientific centers with operational high-flux neutron sources: the Kurchatov Institute (Moscow), the Petersburg Nuclear Physics Institute (Gatchina), the Institute of Metal Physics (Yekaterinburg), and the Joint Institute for Nuclear Research (Dubna).

In the Kurchatov Institute, a IR-8 steady state reactor of 8 MW nominal power and average neutron flux of about 1 x 1014 n/cm2/s is used. The single crystal MOND and powder DISC diffractometers are the main instruments used for crystal studies. The PG double-monochromators are used at both diffractometers, which helps in varying wavelengths over a wide range (0.7 Å - 5.5 Å for MOND) with a 1 x 106 n/cm2/s flux at a sample position if λ=2.4 Å. With the MOND instrument dynamical effects were discovered in neutron magnetic scattering. ('Magnetic Pendellosung effect in neutron scattering by perfect magnetic crystals' Acta Cryst. A, 1992, v.48, 100). Resonance magneto-acoustic and acousto-magnetic effects were experimentally found in perfect crystals of weak ferromagnets. It was found that measured neutron magneto-acoustic resonances are essentially non-linear in nature, which can be seen in the conditions of their stimulation, shape of resonance peaks, and evolution of oscillations over time. It was also established that magneto-acoustic non-linearity is connected with anharmonicity of a magnetic sub-system (Physica B, 1998, v.241-243, 736).

The multi-counter diffractometer DISC is intended for structural studies of microsamples. The low background levels and large solid angle of the detector system allow measurement of diffraction patterns from samples about 1 mm3 in volume in reasonable time. It permits crystal structure studies at very high external pressure in sapphire or diamond anvil cells. The main advantages of these cells are their small dimensions and the possibility of putting them into a refrigerator and cooling them down to helium temperatures. At DISC atomic structures and phase transitions in hydrides, oxides, fullerenes and amorphous substances are studied (see, for instance, 'Pressure induced spin-orientation transition in FeBO3' High Pressure Research, 2000, v.17, 179).

The steady state reactor IVV-2M of 15 MW power (Fig. 1), which operates up to 6000 hours annually, supports the 'Neutron investigations of condensed matter' Centre, which belongs to the Institute of Metal Physics (Yekaterinburg). In this Centre there are several neutron diffractometers and special devices for investigations of physical properties of both conventional and radioactive samples. Among them: a multi-counter high-resolution powder diffractometer (λ=1.515 Å, Δd/d=0.002), two medium-resolution diffractometers, and a multi-counter four-circle single-crystal diffractometer. They are all equipped with special cells for radioactive samples studies in 4.2/1000 range after their irradiation in the reactor core. For high-pressure experiments, cylinder-piston cells up to 1.2 GPa are used. In the Centre, study of the influence of various defects (doping, non-stoichiometry, disorder caused by irradiation with fast neutrons, light or heavy ions, electrons) on crystal structure is the main topic. The main goal of these studies is to study the relation between real (defect) crystal structure and physical properties. In the Centre, studies of structural and magnetic phase transitions, charge ordering in oxides and inter-metallic rare earths or 3d-transition element compounds are also carried out (J. of Alloys and Compounds, 2001, v. 315, 82).

At the Joint Institute for Nuclear Research (JINR) in Dubna, neutron scattering experiments are performed at the IBR-2 pulsed reactor with record average power (2 MW) and pulsed neutron flux (1 x 1016 n/cm2/s). The IBR-2 set-up includes three diffractometers for structural studies of single crystals and powders and three diffractometers for texture and internal stress measurements.

The Fourier high-resolution diffractometer (HRFD) is analogous to the mini-SFINKS facility in Gatchina, but with higher d-spacing resolution (Δd/d=0.001 - 0.0005). A study of mercury-based high-Tc superconductors with various percentages of oxygen or fluorine in the basal plane is an example of an experiment using the HRFD (Figs. 2 and 3). In these studies several results of significance for understanding high-Tc superconductivity in copper oxides have been obtained. Recently, a series of diffraction experiments with doped CMR manganites has been performed. Precision structural analysis of several compounds, including compositions enriched with 18O isotope, provides unique data (Eur. Physical J. B, 2001, v.19, p.215, Fig. 4). HRFD can be used for single crystals if its very high resolution is needed. A typical example of such a problem is the mesoscopic phase separation in La2CuO4+δ, which appears to be due to low-temperature diffusion of extra oxygen. Despite extremely small difference in lattice parameters arising from a homogeneous state, the HRFD helped in measuring split diffraction peaks and in determination of sizes of the coherent regions with antiferromagnetic and superconducting phases (Fig. 5).

DN-12 is a time-of-flight complementary version of the DISC diffractometer for micro-samples. Its parameters allow one to study powders of about 1 mm3 volume inside sapphire or diamond anvils cells. The crystal and magnetic structures of manganites Pr0.7Ca0.3Mn1-yFeyO3 and Pr0.8Na0.2MnO3 with the CMR effect were investigated at pressures up to 4.5 GPa and in a temperature range of 16-300o. In these compounds which have significantly different magnetic structures at normal pressure, stabilization of the AFM state of A-type takes place at high pressures and low temperatures (High Pressure Research, 2003, v.23, p.149 and J. Magn. Mat., 2003, v.267, p.120). With this instrument it is possible to simultaneously measure elastic (diffraction) and inelastic neutron scattering. This mode was used for investigation of structure, phase transitions and atomic dynamics in ammonium halides at pressures up to 10 GPa (High Pressure Research, 2000, v.17, p.251).

The DN-2 diffractometer is used for single crystals. Very high neutron flux (~107 n/cm2/s) at the sample position and an extremely large d-spacing interval available at DN-2 are used in real time experiments with powders. Simultaneously with diffraction patterns, small angle scattering data can also be collected (Fig. 6).

The FSD diffractometer (Δd/d≈0.004) continues the development of neutron Fourier techniques at long-pulse neutron sources, which is carried out in collaboration with PNPI. FSD is optimized for internal stress measurements in bulk materials (Applied Physics A, 2002, v.74, S86). Auxiliary equipment (loading device, mirror furnace, Huber goniometer etc.) allows one to broadly vary experimental conditions. EPSILON (Δd/d≈0.003) is used for stress measurements with rocks. SCAT is a diffractometer with a ring detector intended for texture analysis on rock samples. It is equipped with a high pressure chamber (Pmax≈1.5 x 104 N, Tmax≈700oC) in which the diffraction study of textures of amphibolites and gneisses from the super deep borehole SG-3 in the Kola Peninsula and their analogues from the surface were performed (XXVIII General Assembly of the European Seismological Commission, Italy, Genova, 2002).

Broad perspectives for neutron diffraction studies in Russia will be opened when a new steady state high-flux reactor PIK (W=100 MW), which is under construction in PNPI (Gatchina) opens. Very high neutron flux from PIK, modern equipment, and wide experience in diffraction studies will all help in solving both fundamental and applied problems.

Contact: Anatoly M. Balagurov bala@nf.jinr.ru

L.Ya. Karpov Institute of Physical Chemistry

The X-ray Laboratory in Karpov Institute established in 1938 by G. Zhdanov has become one of the largest centers of X-ray analysis in the former Soviet Union and Russia. The laboratory staff is engaged in projects with chemists from the Russian Federation, Georgia, Latvia, Moldova, the Ukraine, Sweden, Denmark, Spain, Portugal, and South Africa. Several thousand structures have been determined and deposited in the the Cambridge and Karlsruhe databases.

Special procedures have been developed to speed the process of data collection using programs PROFIT (profile fitting) and PAN32 (profile analysis) to treat data collected on Syntex, Nicolet and Enraf Nonius diffractometers. A method has been developed for evaluating the contribution of thermal diffuse scattering (TDS) to structure factors based on scanning peak profiles (program DISCONT). The Rietveld method is also widely used in powder crystal experiments.

High-precision X-ray diffractometry has allowed us to perform electron density studies and a new method for determination of the electron localization function from electron density has been developed. Recently, new computer software for charge density studies (WinXPRO2003) was released as part of a joint project with the Mendeleev University, Moscow.

Contact: www.nifhi.ac.ru/~adam

St Petersburg State University, Department of Crystallography

The Department of Crystallography at St Petersburg State University was established in 1924 by students of E.S. Fedorov. During the last ten years investigations have focused on structural chemistry, structural mineralogy, and crystal growth. Almost every year a national or international conference is organized by the Dept. The XV International Conference on X-ray Diffraction and Crystal Chemistry of Minerals in September, 2003 was organized by the Commissions of X-ray Analysis of Minerals and Crystal Chemistry of the Russian Mineralogical Society RAS. The Department has collaborations with institutes and universities in Germany, USA, Switzerland, Netherlands, and Austria, etc. Below we provide a brief description of the main scientific groups.

The Borate and borosilicate group (Rimma S. Bubnova, rimma_bubnova@mail.ru and Stanislav K. Filatov, filatov@crystal. pu.ru) investigates borate and borosilicate crystals and glasses in collaboration with Peter Paufler (Paufler@physik.tu-dresden.de) at Dresden Technical University, Germany. The first crystal structure determinations of borates at elevated temperatures demonstrated the rigidity of boron-oxygen groups that maintain their configuration and size on heating. Highly anisotropic thermal expansion of 40 borates has been described for the first time and has been interpreted as a result of hinge deformations. (S.K. Filatov, R.S. Bubnova, Phys. Chem. Glasses, 2000, 41, N 5, 216-224).

[S.K.Filatov] S.K. Filatov working at the Bauxite field, Tolbachik volcano, Kamchatka, Russia, in 2000.
Since 1977, 150 minerals of volcanic eruptions from Kamchatka volcanoes were characterized by the Volcanology group (S. K. Filatov, filatov@crystal.pu.ru) in collaboration with Lidia P. Vergasova (vlp@kcs.iks.ru; Institute of Volcanology RAS, Petropavlovsk-Kamchatskiy). In the course of these studies, about 25 new mineral species were discovered, most of them being oxosalts. Many of these structures contain additional oxygen atoms coordinated by four metal atoms M (Cu, Pb, etc.), forming oxo-centered OM4 tetrahedra, a new concept in inorganic crystal chemistry, (S.V. Krivovichev, skrivovi@mail.ru and S.K. Filatov). Microbiological activity was revealed in the transformation of volcanic products to bauxites.

[chromates] Natural (a, b) and synthesised (c, d) pseudomorphs, inheriting (a, c) and losing (b, d) the primary face relief. a, b – goethite after pyrite (Mining Museum collection, St. Petersburg), c – copper chromates after copper vitriol; d – potassium chromates after alum.
The Group of O.V. Frank-Kamenetskaya (Olga@of3102.spb. edu) studies the structure and classification of minerals with atomic defects (solid solutions, mixed crystals, compounds of non-stoichiometric and variable composition). The group uses X-ray based analytical approaches to study chemically inhomogeneous 'single crystals' and have characterized a series of solid solutions (fluorides, sulfides, oxides, silicates). O.V. Frank-Kamenetskaya, I.V. Rozhdestvenskaya, Crystal Chemistry. V. 33, 2nd Revised Edition, SPb: Yanus, 2004.

[boat trip] Boat trip along Neva River: Top row (left to right): S. Ghose (USA), M.G. Krzhizhanovskaya (Russia), Th. Schleid (Germany), G. Ferraris (Italy), V.S. Urusov (Russia), R.S. Bubnova (Russia), P. Paufler (Germany), B. Albert (Germany), V.V. Dolivo-Dobrovol’skiy (Russia). Bottom row: S.K. Filatov and students (Russia), September 2003.
The crystallogenesis group headed by Arkadii E. Glikin (glikin@ag2460.spb.edu) has elaborated upon and extended the fundamentals of crystal formation in solutions to describe solid phase interactions typical of minerals: metasomatic replacement and joint growth of different crystal phases, mixed crystal formation, aggregate recrystallization, epitaxial and quasi-epitaxial overgrowth as well as crystal habit formation. A.E. Glikin. Polymineral-Metasomatic Crystallogenesis. St. Petersburg; Ed. Journal 'Neva', 2004. 320 p. In September 2001, An International Conference on Crystallogenesis and Mineralogy was organized.

The Crystal chemistry of paraffins group (Elena N. Kotelnikova, elena@ek7740.spb.edu, and S.K. Filatov) has studied normal alkanes CnH2n+2 as representatives of the rotatory state of crystalline matter. Experimental data on structural deformations, phase transitions, solid solutions, and phase equilibria of synthetic (n=17-24) and natural (n=17-37) n-paraffins have been obtained and generalized as functions of homological composition and temperature. In additions, phase diagrams of binary paraffin systems have been developed ('Neva', 2002, 352 p. (in Russian)). The First Russian Meeting on Organic Mineralogy was held in 2002 (chairmen: E.N. Kotelnikova and S.K. Filatov).

[crystal structure] Crystal structure of tubular silicate frankamenite Κ3Na3Ca5[Si12O30](OH)F3∙H2O.
The Crystal chemistry of uranyl and heavy metal compounds group (Sergey V. Krivovichev, skrivovi@mail.ru) investigates uranium and heavy-metal minerals and inorganic compounds relevant to the safe disposal of radioactive waste and environmental pollutants (in collaboration with Peter C. Burns, University of Notre Dame, USA). As a result of this joint effort, more than 90 original structure determinations have been completed. This provides a unique basis for understanding the stability of uranium and heavy metal minerals in the environment and their role in environmental pollution.

The Pathology of crystals group of Yurii Punin (Head of the Dept., olga@os2489.spb.edu)
investigates crystal growth instability that leads to the drastic distortion of the outer form and inner structure of crystals during their growth. As a result of this research, a theory of autodeformation defects has been elaborated. The group also developed a complex approach to the problem of growth dissymmetrization and the nature of optical anomalies in crystals on the basis of extensive kinetic and morphological studies of crystal growth in a surface-active environment.

The Tubular silicate group of Ira V. Rozhdestvenskaya (ivrozhdestvenska@mail.ru) works on alkali calcium silicates with tubular radicals, including studies of such exotic silicate minerals as frankamenite, canasite, miserite, tokkoite, tinaksite and agrellite found in charoitite rocks of the Murun massif, western Aldan Shield, southeastern Siberia. They are layer structures that consist of alternating structural modules: walls of Ca-, and Ca, Na-polyhedra with silicate anions located between the walls. The silicate anions form tubes or bent ribbons in wide channels.

X-ray Laboratory, Dept. of Inorganic Chemistry, Faculty of Chemistry.
The laboratory is involved in studies of inhomogenous crystals (solid solutions decomposition, nucleation) and nonstoichiometric compounds (R.A. Zvinchuk, Head of the lab); structures of modified steroid estrogens exhibiting selective biological activity and analysis of structure-property relationships for creation of new drugs (CCDC 164249-164261) (G.L. Starova, starova@VK4829.spb.edu); short-range order in complex stoichiometric 'disordered' oxides with heterovalent isomorphism and Rietveld refinement (Yu.E. Smirnov); and construction of derivative structures on the basis of non-characterictic crystallographic orbits and cyclotomical Patterson's sets.

Contacts have been included in the text.

Laboratory of Diffraction Methods in Kazan

[staff]
In 1996 the Centre of Physical Methods of the Russian Foundation for Basic Research was established at the A.E. Arbuzov Institute of Organic and Physical Chemistry of the Kazan Scientific Centre of the RAS in the Volga region. The laboratory has two CAD4 Enraf-Nonius diffractometers and a scientific staff of two doctors of chemical sciences, four PhDs and several post graduate students. The laboratory performs X-ray diffraction studies for the Arbuzov Institute, for universities and institutes of Kazan, as well as for research institutes of the Volga region, Ekaterinburg, Ufa, Irkutsk, and St Petersburg. About 200 structures of organic, phosphorus-containing, organoelement and metalloorganic compounds are studied annually.

[scheme] Geometry of substituted 5,6-benzo-1,2-oxaphosphorin-3-ene and the system of hydrogen bonding in the crystal.
Major research at the institute involves the synthesis and structures of phosphorus compounds, macrocyclic and cage organic compounds, and supramolecular chemistry using a variety of physical methods. I.A. Litvinov conducted a series of experiments on cyclic phosphorus-containing compounds including unsaturated 6- and 7-membered phosphaheterocycles. It was shown that a model of hyperconjugative stereoelectronic interactions can describe the position of the substituents on the phosphorus atom, as well as the variations of molecular geometry in the absence of strong intermolecular interactions, such as hydrogen bonding.

[localised hydrophobic and hydrophilic regions] Schematic representation of localized hydrophilic and hydrophobic regions.
Recent studies have revealed a pattern of localized hydrophobic and hydrophilic domains in supramolecule systems. Analysis of a variety of crystals revealed 4 types of packing depending on the ratio of hydrophilic and hydrophobic regions; homogeneous, spherical, cylindrical, and lamellar. The type of packing correlates with the symmetry of a crystal. Lamellar packing is observed only for low symmetry (triclinic - orthorhombic) rod type crystals and for low symmetry tetragonal and trigonal crystals, while homogeneous and spherical domains can be observed in all crystals, even in cubic systems.

[molecular complex] Geometry of molecular complex of isosteviol with dimethylaniline.
A series of investigations of molecular complexes of isosteviol revealed that isosteviol forms isostructural tetragonal crystals in molecular complexes with aromatic compounds having a guest-host ratio of 1:2. This phenomenon may be used to separate spatial isomers of aromatic compounds.

Contact: Igor Litvinov litvinov@iopc.knc.ru

Kurnakov Institute of General and Inorganic Chemistry, Moscow

[researchers] Researchers in the Laboratory of Crystal Chemistry of Coordination Compounds.
In the Kurnakov Institute of General and Inorganic Chemistry, there are two laboratories that study crystal structures of different classes of compounds, namely, the Laboratory of Crystal Chemistry of Coordination Compounds and the Laboratory of X-ray Structure Analysis. The Laboratory of Crystal Chemistry of Coordination Compounds was founded in 1945 by G.B. Bokii, who led the laboratory until 1959. In 1959-1990, the laboratory was headed by M.A. Porai-Koshits, and since 1990 it has been headed by V.S. Sergienko.

[researchers] Researchers in the Laboratory of X-ray Structure Analysis.
For many years the wide variety of interests of M.A. Porai-Koshits determined the compounds studied in the laboratory: complexes of Group V-VII metals with multiple metal-oxygen bonds; isopoly- and heteropolycompounds; binuclear complexes of Rh and other Group VIII metals containing metal-metal bonds; d-metal complexes with organic chelating O-, N-, and S-donating and macrocyclic ligands; heterometal clusters; optically active Pt complexes with amino acid ligands; mono-, di-, and triaminocarboxylates and their mono- and diphosphonate analogues; isoquinoline derivatives and their complexes; amino- and phosphoryl-containing podands; and mixed-ligand Au(I) and Hg(II) complexes.

New projects at the laboratory include:

(1) Investigation of a wide spectrum of secondary interactions (traditional hydrogen bonds, C-H…π contacts, proton-hydride, attractive, agostic, and stacking interactions, etc.) that play an important role in the formation of crown-ether styryl dyes, charge-transfer complexes based on π-donating bis(18-crown-6)stilbenes, diaryl esters exhibiting liquid-crystalline properties, and dipyridyls and their coordination polymers with Ag(I).

(2) The trans effect of multiply bound peroxo ligands in pseudo octahedral VO(η-O2)L4 complexes (where L is a donor atom of a monodentate and/or polydentate ligand) was characterized and the structures of the Group IV-VI metal (Ti, Ta, V, Nb, Mo, W) oxoperoxo complexes of this type were analyzed;

(3) Specific features of regioselective acid-catalyzed substitution of exo-polyhedral hydrogen atoms in the decaborate anion B10H102- were studied. The main product of these reactions is the equatorially monosubstituted derivative.

(4) Structures of LaL3(Phen)n mixed-ligand complexes (where L is dipivaloylmethanate or hexafluoroacetylacetonate) were determined to establish correlations between the structure and luminescence properties.

[postage stamp] The Soviet postage stamp devoted to the 50th anniversary of foundation of the Kurnakov Institute of General and Inorganic Chemistry. The figure on the stamp represents the [Re2Cl8]2- structure.
The Laboratory of X-ray Structure Analysis was organized in 1934 by N.V. Ageev (1934-1953) and N.G. Kuznetsov (1953-1979). Yu.N. Mikhailov has been the head of the laboratory since 1979. The studies performed in the laboratory are related to the interests of other laboratories of the Institute, including the relationships between the composition, structure, and properties of coordination and inorganic compounds. One of the most interesting results was obtained in the laboratory in the 1960s when the first quadruple rhenium-rhenium bond was revealed in the [Re2Cl8]2- anion. Later, the interpretation of this bond was confirmed by F.A. Cotton. During the last five years, investigations of monomeric, dimeric, and trimeric compounds of rhodium, iridium, molybdenum, and platinum at different oxidation states have been performed along with the studies of polynuclear compounds containing complex metal-metal bond systems.

Important results have been obtained for nontransition p elements at low oxidation states. Mixed-ligand polymeric compounds of tin(II) with nitrogen-containing organic cation supramolecular compounds having large hollows and channels. Some uranyl complexes with fluoride ligands and tetradentate bridging oxalate ions contain infinite channels approximately 7-10 Å in cross-section. Channels that are formed by cyclic dioxygen anions were found in the structures of some boratobismuthates, the high-temperature modification of Na2B4O7, and double potassium-bismuth citrate.

A large series of mixed-cation RE compounds with condensed anions (phosphates, phosphatoborates, phosphatogermanates, germanates, oxophosphatovanadates) have been studied to reveal the effect of cations on the structure of the anionic group. It was found that in the noncentrosymmetric ultraphosphates, the (P8O23)6- anion contains isolated oligomers consisting of three connected six-membered rings. These compounds are candidates for quantum electronics. In the last three years, efforts have involved structural studies of polymeric coordination compounds of tin, bismuth, and uranyl with bridging oxo anions, polymeric complexes of silver with nitrogen- containing organic compounds, supramolecular compounds of doubly and triply charged metals with hexamethylenetetramine and different aminopolycarboxylic acids. Crystal structures of these compounds contain large hollows and channels that can be used for preparation of molecular sieves and ion exchangers. Over 150 crystal structures a year are determined by two groups using two Enraf-Nonius CAD-4 diffractometers.

Contacts: V. S. Sergienko (sokol@igic.ras.ru), Yu. N. Mikhailov (mikhailov@igic.ras.ru)

Electron density at Mendeleev University

Research in the Mendeleev University group, headed by Vladimir Tsirelson, deals with describing bonding in solids in terms of electron density and electrostatic potential, as well as related functions describing local energies and potentials. Early studies were based on the Bader's quantum mechanical topological theory, which was applied to experimental electron density for the first time by Tsirelson and Streltsov in 1985. This approach is now widely accepted. The extensive range of compounds studied spans simple and binary crystals, perovskites, spinels, garnets, silicates, and molecular crystals. The materials were studied using topological theory to quantify atomic and molecular interactions and to elucidate the physical nature of the spatial architecture of crystalline systems.

Other studies are devoted to topological analysis of the electrostatic potential in molecules and crystals. It has been demonstrated that the nuclei of neighboring atoms are separated in the inner-crystal electric field by surfaces of the zero-flux potential gradient, inside of which the nuclear charge is completely screened by an electronic cloud. These electrically neutral bonded pseudoatoms define the regions in a crystal dominated by a charge of one or another nucleus, no gradient lines connecting the anions were found. The results led to a physically reasonable description of the Coulomb field features in a system, which is a key point in the development of corresponding models for force field.

[poster]
Most recently fundamental research has been performed in collaboration with the X-ray laboratory of the Karpov Institute to combine experimental electron density with the formulae of density functional theory to calculate kinetic energy, potential energy, and exchange energy, etc. It has been shown that maps of kinetic and potential energy densities explicitly reveal features of electronic energy resulting from the molecule or crystal formation, while the integral values of these functions over the atomic basins yield the components of the electronic energy for the bounded atoms. Becke et al.'s electron localization function and localized-orbital locator (see figure) and Parr et al.'s local temperature and local internal entropy of electron gas have also been approximately expressed in terms of electron density and its derivatives. As a result, X-ray diffraction experiments have been extended to provide detailed descriptions of atomic and molecular interactions in a crystal in a form compatible with a quantum mechanical picture.

Contacts: Vladimir G. Tsirelson tsirel@muctr.edu.ru

Inorganic structure in Samara

[cavity] (a)
[substrate] (b)
Molecular Voronoi-Dirichlet polyhedra (a) of a cavity and (b) of a substrate molecule inside a cucrbit[6]uril molecule.
At Samara State University (SSU) crystallographic and crystallochemical research is conducted in the department of inorganic chemistry. Basic areas of study include: (i) development of computer methods for crystallochemical analysis (V.N. Serezhkin, V.A. Blatov, A.P. Shevchenko), (ii) structure and properties of uranium complexes (L.B. Serezhkina) and compounds containing atoms with lone pairs (D.V. Pushkin).

At present SSU researchers are working on a unique program package (TOPOS) for multi-purpose crystallochemical analysis (a user manual and demo and beta versions are available at www.topos.ssu.samara.ru/). TOPOS is an integrated interactive shell that supports a relational crystal structure database. To analyze crystal structure information TOPOS uses methods based on the quantitative characteristics of Voronoi-Dirichlet polyhedra that avoid using crystallochemical radii or a priori assumptions concerning the nature of interatomic bonds. The methods provide for unified analysis of crystalline substances at the atomic, molecular and supramolecular levels. Commercial and non-commercial versions of TOPOS are installed in a number of institutes of the RAS and in universities in France, Japan, Italy, Spain, and the UK.

[researchers] Bottom row (left to right): L.B. Serezhkina and V.N. Serezhkin; back row: D.V. Pushkin, V.A. Blatov, and A.P. Shevchenko.
TOPOS was created to (i) implement and combine computer methods of crystallochemical analysis within a unified data-analytical system; (ii) provide resources for the complex automatic analysis of large groups of chemical compounds to search for common crystallochemical features; and (iii) maintain objectivity while performing crystallochemical analysis.

TOPOS provides the user with tools to (i) calculate coordination numbers of atoms or molecules, (ii) assess a number of geometrical characteristics of atomic and molecular domains; (iii) estimate stereo effects caused by lone pairs or by the Jahn-Teller effect; (iv) analyze the far coordination spheres of atoms or molecules, and study the topology of atomic and molecular packing; (v) search for topological relationships between chemically and stoichiometrically different crystal structures, perform crystallochemical classification; (vi) estimate sizes of voids, cavities and channels in crystals, reveal agostic contacts and non-valence interactions; and (vii) predict stability of coordination compounds and supramolecular aggregates.

Various aspects of TOPOS have been demonstrated by analyzing different inorganic and coordination compounds including σ- and π-complexes, minerals, superionic conductors, zeolites, etc. Using uranium(VI) compounds as an example it was shown that the solid angles by which the faces of a Voronoi-Dirichlet polyhedron are 'seen' from the nucleus of a complexing atom can be used to evaluate the electron-donor capabilities of oxygen-containing ligands with the 18 electron rule. It has been proven that using the ligand electron-donor characteristics obtained with crystal structure data, one can predict the directions of stepwise complexation in water solutions as well as the composition and structure of resulting uranium(VI) complexes.

Contacts: serezhkin@ssu.samara.ru

This extract from 50 Years of X-ray Diffraction, edited by P. P. Ewald and published in 1962, recounts the early development of crystallography in this region.

[pdf icon]CHAPTER 24

Schools of X-ray Structural Analysis in the Soviet Union

by A. V. Shubnikov

The discovery of X-ray diffraction coincided with the centennial celebration of the eviction of Napoleon from Russia. The Czarist government attempted to use this day for boosting the patriotic spirit of the people, but without much success. In 1911 a mood of opposition prevailed among students and professors which was brought about by mass discharges of students and professors from universities, the closing of a series of departments at universities, and other measures taken by the Minister of Public Education, L. A. Kasso. Among the creative workers in the field of crystallography who left the Moscow University were V. I. Vernadskii, A. E. Fersman, Ia. V. Samoilov, and G. V. Wulf. At that time I was finishing my studies at the Moscow (State) University, working under the guidance of G. V. Wulf on a paper on the symmetry of K2Cr2O7 crystals, and at the same time acting as the unofficial assistant of my teacher at the Peoples' City University. The further research and teaching activities of G. V. Wulf continued at this Peoples' University, organized with great difficulties from private means in Moscow in 1908. A year before the described incidents in Moscow the well-known Russian crystallographer E. S. Fedorov, the Director of the Mining Institute in Petersburg named for Empress Catherine II, was discharged from his post (approval not granted by Minister Timashev after a second election by the Scientific Council of the Institute). This was the general picture of the political circumstances which befell Russian crystallographers in the year of Laue's magnificent discovery.

Despite the extremely unfavourable circumstances for the flourishing of the Sciences which prevailed in Czarist Russia at the beginning of the 20th century, crystallography in this country was developed to a rather high level. This was evidenced by the fact that at the time of Laue's discovery, a series of original textbooks had been written for the teaching of crystallography at higher schools. Research in the field of crystallography underwent intensive development and was concentrated around two schools: the Petersburg school, headed by Fedorov at the Mining Institute, and the Moscow School, headed by Wulf at the Peoples' University. Their many similarities notwithstanding, these two schools essentially differed from each other in the purpose, the method, and the role of crystallography in the development of Natural Sciences.

In his renowned courses of crystallography, Fedorov treated crystallography as the 'base of all sciences of inorganic nature'. He placed theoretical crystallography 'on the same level with the most precise of the existing sciences'. Fedorov was of the opinion that theoretical crystallography could be built up, 'without the risk of even the smallest conflict with experimental data', from the 'initial experimental state of crystallography' and the 'immutable fact', which was that 'all particles of a crystalline substance are identical and arranged in parallel positions', that these particles - 'crystalline molecules' - taken as a whole 'completely fill space', and that the 'parallelohedra should be considered as portions of space, belonging to separate crystalline molecules'. It is interesting to note that Fedorov remained faithful to this 'basic law' even after the completion of the space-group derivation (1900) which clearly indicated that a non-parallel arrangement of identical particles was possible. It should be added that Fedorov did not follow up his conclusion because he assumed that crystals belonging to asymmorphic groups could not exist in nature. His Brief Course of Crystallography, published ten years after the derivation of the space groups, does not even mention these groups.

My teacher Wulf held different views of crystallography. In contrast to Fedorov who over-estimated crystallography, considering it as the 'base of all sciences of inorganic nature', Wulf under-estimated crystallography, which, in his opinion was simply a 'chapter in physics', 'did not deserve to be called a separate science'. Combining forces with physicists (Voigt), Wulf, identified crystallography with the 'study of a solid as a certain medium'. In this Wulf definitely set himself apart from mineralogists who, until recently, considered a crystal as an 'individual of inorganic nature'. Wulf was disturbed because the idea of crystallography as a part of physics did not find unanimous acceptance; for this reason, our university does not include crystallography in its physics course.

Von Laue's discovery left very deep impressions on the two schools of crystallography in Russia and brought with it different reactions from the leaders of these schools.

When the news of the discovery of X-ray diffraction reached Wulf, he immediately expressed his desire to work in this field. Studying von Laue's equations to the very end, Wulf derived from them the relationship

λ/2 = Δε/m,

which is of identical meaning with Bragg's well-known formula

nλ= 2d sin θ

The paper was published in Phys. Zs. 1913, 14, 217. All of Wulf's further scientific work was largely determined by von Laue's discovery. In 1916 Wulf translated into Russian the book by W. H. and W. L. Bragg - X-rays and Crystal Structure.

Fedorov's reaction to Laue's discovery was quite different. Evaluating correctly the 'change brought about in crystallography by the application of X-rays to the study of crystals', Fedorov could not overlook the fact that new experimental data of the structures of diamond, rocksalt, and other crystals refuted the 'unalterable fact' (the unfailingly parallel distribution of identical particles in a crystal), which is contained in the 'basic law'. Compelled to acknowledge that 'under no circumstances can crystals be considered as simple space lattices of particles', Fedorov nevertheless attempted in various ways to change this law, but without success. Fedorov passed away in 1919, in Leningrad.

Fedorov's students at the Leningrad Mining Institute attempted to organize experimental research in the field of X-ray structural analysis. However, the difficult post-war days seriously impeded these attempts. Somewhat more favourable conditions existed in Moscow, where Wulf was in charge of studies by means of X-ray diffraction, It must be emphasized, however, that this work in Leningrad as well as in Moscow developed extremely slowly. It need be said only that until the death of Wulf (in 1925), the crystal structure of only one substance (NaClO3) had been studied in our country, by Wulf himself. The next twenty years could be characterized also as a preparatory period for serious experimental research in the field of X-ray structural analysis.

The research in this field underwent an intensive development only after World War II and was localized in certain research centres in Moscow: the Institute of Crystallography of the Academy of Sciences, USSR, under the supervision of N. V. Belov; the L. Ia. Karpov Physico-Chemical Institute, under the supervision of G. S. Zhdanov; the Institute of General and Inorganic Chemistry of the Academy of Sciences, USSR, and the Moscow University, under the supervision of G. B. Bokij; and the Institute of Organic Chemistry of the Academy of Sciences, USSR, under the supervision of A. I. Kitaigorodskii.

Belov devoted his studies to the structure of silicates. In collaboration with his numerous students Belov succeeded in deciphering a whole series of very complex silicate structures (ilvaite, epidote, zoisite, cuspidine, xonotlite, wollastonite, gadolinite, seidoserite, lovenite, lovoserite, epididymite, rhodonite, and hillebrandite) . 'Direct' methods of X-ray structural analysis were, and still are, developing parallel to the experimental research in Belov's school. The complex methods of structural calculations are now carried out by machines. Belov is now rightfully accepted as the leading figure in the field of structural crystallography in our country and an outstanding expert of space groups.

Zhdanov is known here as the author of the first textbook on X-ray analysis. At the beginning of his independent scientific activities, Zhdanov had a somewhat limited choice in the selection of substances for his studies which had to be in the field of interest of the Karpov Institute. This resulted in studies of the crystal structures of a series of inorganic compounds (carbides, cyanides, rhodanides, borides, oxides), and organic substances (nitro and halogen derivatives of naphthalene and benzene, organometallic substances, and organic dyes). At the present time Zhdanov is interested in crystals with special physical properties (ferroelectrics, piezoelectrics, superconductors, and others). This research is being conducted at the Department of Solid State Physics of the Moscow University.

Bokij chose complex compounds as the object of his crystal chemical investigations. A new group of complex compounds with multiple bonds (within the molecule) was discovered and investigated recently. The crystal chemical theory of daltonides and bertolides was formulated. The Department of Crystallography and Crystal Chemistry was organized by Bokij under the Geological Faculty of the Moscow University. His scientific work has been conducted primarily at the Institute of General and Inorganic Chemistry of the Academy of Sciences, USSR. Bokij is the author of the book Crystal Chemistry (1960), and editor of the Journal of Structural Chemistry, in the founding of which he has been instrumental. Among Bokij's numerous students, M. A. Porai-Koshits deserves special mention.

Organic crystal chemistry is the speciality of A. I. Kitaigorodskii. The underlying idea of this science, according to the author, is the close-packing of nonspherical particles - molecules - , i.e. arrangements of molecules such that the 'protrusions' of one molecule fit into the 'depressions' of the other. This idea is developed in detail by A. I. Kitaigorodskii in his book, Organic Crystal Chemistry (1955), and is substantiated in studies by the author and his students and by thorough investigations of the structures of organic crystals according to data available in literature. Kitaigorodskii is known here as the author of basic textbooks on X-ray structural analysis.


First published for the International Union of Crystallography 1962 by N.V.A. Oosthoek's Uitgeversmaatschappij, Utrecht, The Netherlands
Digitised 1999 for the IUCr XVIII Congress, Glasgow, Scotland
© 1962, 1999 International Union of Crystallography

Photographic record of crystallographic activities in Russia

The complete IUCr photographic archive includes thousands of photographs. Here we include a collection illustrating activities in this country. This image is selected randomly from the galleries listed below (Portraits of Russian crystallographers, undated).
Yuri Timofeevich Struchkov (1926-1995).