Abstract
Electrocatalytic reactions involve interfacial interactions between the surfaces of electrodes and reactive species at an electrolyte interface. There are presently no universal or unambiguous methods to directly assay the active top atomic layer composition that influences reactivity of these electrodes under relevant operating conditions. Low energy ion scattering (LEIS) spectroscopy is a surface characterization technique that yields compositional analysis of the outermost atomic layer of a material, but it must be performed in ultra-high vacuum (UHV). Application of LEIS measurements to electrochemical materials that are removed from ambient liquid phase environments thus leaves an open question as to whether the surface that is transferred to UHV is truly the surface that manifested during electrochemical reaction. Toward the goal of preserving the active surface state, we developed a sample transfer workflow for LEIS enabling air-free removal and drying of an electrode from an electrochemical cell while maintaining control of the potential using an auxiliary electrode. The potential-controlled emersion method was demonstrated to give distinct potential-dependent surface compositions for a Cu-Pd alloy relative to removal after uncontrolled return to open circuit potential. A Cu-enriched surface was found at anodic potential and a Pd-enriched surface at cathodic potential, suggesting that the approach can be used to retain representative atomic configurations during transfer. Since adsorbates will often persist from the reaction environment, conventional sample pretreatment methods for removal including atomic O and atomic H exposure were also contrasted. Both methods were found to differ with results from incidental low-dose depth profiling by the HS-LEIS primary ion source, which removes adventitious species and surface atoms during the course of repeated measurement. These depth files were found to be sensitive to sample history and thus qualitatively informative in spite of the possible changes induced by ion damage. The results exhibit (i) the need for complete control over the polarization state of the sample at all times (no excursions to open-circuit during transfer) and (ii) the utility of low-dose depth profiling to capture changes in the near-surface composition.
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