Another step of the APXPS evolution taken at MAX IV synchrotron

Slavomir Nemšák
[Figure1]
Figure 1. An artistic view of the ambient-pressure hemispherical analyzer entrance aperture in a gaseous and liquid environment. Credit: Tomas Duchon, https://micronano.net/.

In the past several decades, X-ray photoelectron spectroscopy (XPS) has been established as a versatile tool to investigate chemical and electronic properties of materials. Its principle is based on a photoelectric effect, which was discovered by Hertz (1887) and explained later by Einstein (1905). However, a practical technical implementation of the technique had to wait until the 1940s, when Siegbahn et al. carried out their first pioneering experiments (Siegbahn & Svartholm, 1946).

XPS uses X-ray photon beams, which excite photoelectrons that are emitted from a material. Due to a strong interaction of electrons with solids, liquids and also gases, the technique was initially designed to work with solid samples under ultra-high vacuum only. Even though the early experiments on liquids performed by Siegbahn et al. were carried out in the 1970s (Siegbahn & Siegbahn, 1973), it was the development of modern differentially pumped hemispherical analyzers with focusing pre-lens (Figure 1) in the early 2000s that paved the way to widespread deployment of XPS systems capable of measurement under ambient pressure (typically tens of mbar) around the world (Salmeron & Schlögl, 2008).

In the paper by Zhu et al. (2021), a new ambient-pressure XPS (APXPS) setup installed at the HIPPIE beamline in MAX IV laboratory in Lund, Sweden, is introduced. It is a state-of-the-art system that was designed to be both modern and versatile to serve a wide scientific community. HIPPIE is an undulator beamline, which covers energies ranging from 250 to 2200 eV and provides high flux (>1012 photons s−1) even at high energy resolving powers (∼10000). The upper boundary of this energy range is especially important due to the fact that it is the higher kinetic energy of photoelectrons that is needed to overcome attenuation of the electron signal in the gas or liquid environments. Simply speaking, the ability to perform XPS experiments at higher pressures relies on using higher photon excitation energies, pushing the boundaries from soft to hard X-ray excitation.

In order to cover a variety of scientific disciplines, a modular setup allows switching between two concepts: a cell-in-cell design and a backfill ambient-pressure chamber. The first focuses on solid/gas interface studies, catalysis and rapid gas reactions analysis. The second specializes in liquid chemistry and operando electrochemistry.

Another highlight of the instrument is the multimodal approach that includes infrared reflection absorption spectroscopy (IRRAS), which has been demonstrated earlier (Head et al., 2017), but at HIPPIE is now an integral part of the experiment. The combination of the high photon flux of the HIPPIE beamline and the fast collection of the electron signal using a CMOS camera enables high-rate spectra acquisition in approximately millisecond time-scales. Apart from static-solid and liquid samples, the setup can also make use of a microjet liquid delivery. Last, but not least, the gas handling system provides automatic mixing of up to eight gases in pressures ranging from ultra-high vacuum to 30 mbar. A small volume of the cell-in-cell design allows a rapid gas exchange in a matter of seconds.

The authors demonstrate the capabilities of the newly built instrument using several scientific examples. The first is monitoring hydrogen gas intercalation under graphene flakes in real time. These time-resolved experiments show how the gas delivery system, providing a train of pressure pulses of hydrogen and oxygen gases, works together with the high spectra acquisition rate. Spectral signatures of graphene with and without intercalated hydrogen are successfully time-correlated with the arrival of hydrogen gas pulses.

Another demonstration uses a lithium/lithium cobalt oxide battery in an in situ electrochemical cell. The lithium cobalt oxide electrode was monitored during charging/discharging of the battery. Thanks to the chemical specificity of the APXPS, the team of authors observed a change in the oxidation state as well as electronic structure of the cobalt present in the electrode as lithium was extracted/incorporated into the electrode.

The last scientific example presented in the paper is relevant to catalytic studies. Adsorption of carbon monoxide on a platinum single crystal is studied both by APXPS and IRRAS. Combination of these two methods permitted unambiguous identification of carbon monoxide occupying bridge and top adsorption sites of Pt(111) and their population under changing carbon monoxide background pressure.

These three scientific demonstrations showcase the versatility and strengths of this newly built experimental setup at MAX IV synchrotron. The field of APXPS has undergone dramatic developments in the last two decades. Faster acquisitions, a use of multiple complementary probes and a high level of automation makes the HIPPIE facility another successful iteration in this highly evolving field and a significant achievement, which will benefit all prospective users and the scientific community as a whole.

References

Einstein, A. (1905). Ann. Phys. 322, 132–148.

Head, A. R., Karslıoğlu, O., Gerber, T., Yu, Y., Trotochaud, L., Raso, J., Kerger, P. & Bluhm, H. (2017). Surf. Sci. 665, 51–55.

Hertz, H. (1887). Ann. Phys. Chem. 267, 983–1000.

Salmeron, M. & Schlogl, R. (2008). Surf. Sci. Rep. 63, 169–199.

Siegbahn, H. & Siegbahn, K. (1973). J. Electron Spectrosc. Relat. Phenom. 2, 319–325.

Siegbahn, K. & Svartholm, N. (1946). Nature, 157, 872–873.

Zhu, S., Scardamaglia, M., Kundsen, J., Sankari, R., Tarawneh, H., Temperton, R., Pickworth, L., Cavalca, F., Wang, C., Tissot, H., Weissenrieder, J., Hagman, B., Gustafson, J., Kaya, S., Lindgren, F., Källquist, I., Maibach, J., Hahlin, M., Boix, V., Gallo, T., Rehman, F., D'Acunto, G., Schnadt, J. & Shavorskiy, A. (2021). J. Synchrotron Rad. 28, 624–636.

This article was originally published in J. Synchrotron Rad. (2021). 28, 373–374.

12 March 2021

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