Environmental cells for vacuum spectroscopies at ambient pressures
The requirement of high vacuum in conventional electron spectroscopy studies such as X-ray Photoelectron Spectroscopy (XPS), Auger Electron Spectroscopy (AES) and Electron Energy Loss Spectroscopy (EELS) imposes a major obstacle for analyzing interfacial physical and chemical processes under ambient pressure conditions. Consequently, there have been large efforts, mainly in the field of heterogeneous catalysis and environmental remediation, to overcome this so-called “pressure gap” in order to observe processes taking place at surfaces and interfaces under in operando conditions, namely elevated or ambient gas pressure or liquid environments. The performance of new materials and devices, in fact, often depends on processes taking place at the interface between an active element and some environment, such as air, water or another fluid. Understanding these processes often requires surface specific spectroscopic data acquired under real operating conditions, which can be challenging because standard approaches such, as said above, generally require high vacuum environments.
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Figure 1: schematic view of the procedure used for the production of the environmental cells. a): focused ion beam assisted milling of a micron-sized hole in the primary SiO2 membranes; b): deposition of the GO membranes over the orifices; c): deposition of the liquid solution in the container; d): sealing of the cell with a Si wafer and UV curable adhesive.
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Existing approach to this problem relies on unique and expensive apparatuses equipped with electron energy analyzers coupled with sophisticated differentially pumped lenses. Alternatively, liquid micro jets and droplet “trains” methods have also been implemented to probe the analytes inside highly volatile solvents. In spite of the tremendous success, these state-of-the-art instruments are currently accessible only at a few laboratories and synchrotron radiation facilities, thus restricting the span of the research to a small number of users.
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Research groups of the Southern Illinois University (USA) lead by Andrei Kolmakov, Northwestern University (USA), Sincrotrone Trieste and Technische Universität München (Germany) have realized a simple environmental cell using graphene oxide windows that are transparent to low-energy electrons (down to 400 eV) produced by soft X-rays. They performed proof-of-principle X-ray Photoelectron Spectroscopy measurements on model samples such as gold nanoparticles placed on the back side of the membrane and aqueous salt solution. Graphene-oxide (GO), graphene and other emerging atomic membrane windows could be used to make low-cost single-use environmental cells that are compatible with commercial X-ray, electron microscopes or optical instruments. In Figure 1 a schematic procedure for the production of the environmental cells is reported. The Graphene Oxide sheets were produced by known synthesis purification procedures; to ensure the mechanical stability of the suspended GO windows, small 3-10 µm holes were milled by a focused ion beam in the primary membranes and the individual ca 100-1000 µm2 GO single sheets were deposited over these orifices by a Langmuir-Blodgett technique. |
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This research was conducted by the following team:
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Andrei. Kolmakov – Southern Illinois University, Carbondale, Illinois, USA.
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Dmitriy A. Dikin, Laura J. Cote, Jiaxing Huang, Northwestern University, Evanston, Illinois 60208, USA.
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Majid Kazemian Abyaneh, Matteo Amati, Luca Gregoratti and Maya Kiskinova, Sincrotrone Trieste S.C.p.A., Trieste, Italy.
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Sebastian Günther, TU München, Chemie Department, Garching, Germany
Research funding: the SIUC part of the research was supported through NSF ECCS-0925837 grant. L.J.C and J.H. were supported by NSF through a CAREER award (DMR 0955612)
