Surface Analysis for Electrochemistry: Ultrahigh Vacuum Techniques

Abstract: The study of processes that transpire at heterogeneous interfaces is an exceedingly difficult proposition. No single experimental technique can ever hope to unravel all the nuances of heterogeneous reactions; hence, in surface science, the use of multiple complementary methods is not uncommon. Ultrahigh vacuum electrochemistry (UHV/EC) is a term ascribed to the approach that rests upon the integration of classical electrochemical methods with surface‐sensitive analytical techniques; this strategy parallels tha… Show more

“…However, the surface oxide can be removed in oxygen free and acidic solutions by electrochemical reduction in the negative potential regime with respect to the metal's equilibrium potential [53]. Alternatively, for the application of these materials as electrochemical nanoelectrodes a transfer chamber can be used if the tip potential must be kept above the metal's reduction potential, especially in basic electrolytes [53][54][55][56]. This behaviour restricts the application of not noble metal tips and favours the use of gold tips in electrochemical environment.…”

Electrochemical nanoelectrodes for advanced investigations of nanostructures

“…However, the surface oxide can be removed in oxygen free and acidic solutions by electrochemical reduction in the negative potential regime with respect to the metal's equilibrium potential [53]. Alternatively, for the application of these materials as electrochemical nanoelectrodes a transfer chamber can be used if the tip potential must be kept above the metal's reduction potential, especially in basic electrolytes [53][54][55][56]. This behaviour restricts the application of not noble metal tips and favours the use of gold tips in electrochemical environment.…”

Electrochemical nanoelectrodes for advanced investigations of nanostructures

“…illustrative cases involving the electrodeposition of ultrathin metal films of varying reactivities onto noble-metal substrates were investigated: (i) Pd on Pt(111), a noble admetal on a noble-metal surface; (ii) Bi on Pd(111), a less noble admetal on a noble-metal surface; and (iii) Co on polycrystalline Pd and Pd(111), a reactive metal on a noble-metal surface. The interfacial electrochemistry of these prototypical systems was characterized using a combination of electrochemical methods (voltammetry and coulometry), ultrahigh vacuum electron spectroscopies (Auger electron spectroscopy, low energy electron diffraction, and X-ray photoelectron spectroscopy) [2] and in situ scanning tunneling microscopy [3].…”

Electrodeposition of Ultrathin Films on Well-Defined Noble-Metal Electrodes: Studies by UHV-EC-STM

“…Texas A&M University College Station, TX 77843 USA Three illustrative cases involving the electrodeposition of ultrathin metal films of varying reactivities onto noble-metal substrates were investigated: (i) Pd on Pt(111), a noble admetal on a noble-metal surface; (ii) Bi on Pd(111), a less noble admetal on a noble-metal surface; and (iii) Co on polycrystalline Pd and Pd(111), a reactive metal on a noble-metal surface. The interfacial electrochemistry of these prototypical systems was characterized using a combination of electrochemical methods (voltammetry and coulometry), ultrahigh vacuum electron spectroscopies (Auger electron spectroscopy, low energy electron diffraction, and X-ray photoelectron spectroscopy) [2] and in situ scanning tunneling microscopy [3].…”

Electrodeposition of Ultrathin Films on Well-Defined Noble-Metal Electrodes: Studies by UHV-EC-STM