open access publication

Article, 2021

Scanning probe microscopy for electrocatalysis

Matter, ISSN 2590-2393, 2590-2385, Volume 4, 11, Pages 3483-3514, 10.1016/j.matt.2021.09.024

Contributors

Wang, Yuqing 0000-0002-5853-932X [1] Skaanvik, Sebastian Amland [1] Xiong, Xuya 0000-0001-9554-1974 [1] Wang, Shuangyin 0000-0002-5848-1762 (Corresponding author) [2] Dong, Ming-Dong 0000-0002-2025-2171 (Corresponding author) [1]

Affiliations

  1. [1] Aarhus University
    2. [NORA names: AU Aarhus University; University; Denmark; Europe, EU; Nordic; OECD];
  2. [2] Hunan University
    3. [NORA names: China; Asia, East]

Abstract

The development of high-efficiency energy storage and conversion devices requires a deeper understanding of the structure-activity relationship of electrocatalysts, material transformations during electrocatalysis processes, and complex electrochemical processes at electrode-electrolyte interfaces. Scanning probe microscopy (SPM) is a powerful tool for visualizing the surface properties and localized electrochemical activity down to the atomic scale in situ and even operando, thus plays an essential role in studying heterogeneous electrocatalysis mechanisms. We summarize recent advancements in SPM for investigating energy-related electrocatalysis based on three unique characteristics of SPM—surface property imaging, in situ/operando monitoring, and nanoscale electrochemical mapping,outline the application of SPM in investigating the structure-activity relationship, material transformations, and electrochemical processes. The specific SPM techniques discussed here include scanning tunneling microscopy, atomic force microscopy, scanning electrochemical microscopy, scanning ion conductance microscopy, and scanning electrochemical cell microscopy. Finally, the opportunities and challenges of SPM in electrocatalysis are discussed.

Keywords

activity, application of scanning probe microscopy, applications, atomic force microscopy, cell microscopy, challenges, complex electrochemical processes, conversion, conversion devices, development, devices, electrocatalysis, electrocatalysis mechanism, electrocatalysis process, electrocatalysts, electrochemical activity, electrochemical mapping, electrochemical microscopy, electrochemical processes, electrode-electrolyte interface, energy storage, energy-related electrocatalysis, force microscopy, high-efficiency energy storage, images, interface, local electrochemical activity, maps, material transformation, materials, mechanism, microscopy, monitoring, nanoscale, opportunities, probe microscopy, process, properties, property images, relationship, scanning, scanning electrochemical cell microscopy, scanning electrochemical microscopy, scanning ion conductance microscopy, scanning probe microscopy, scanning probe microscopy techniques, scanning tunneling microscopy, storage, structure-activity relationship, surface, surface properties, technique, transformation, tunneling microscopy, unique characteristics

Funders

  • Danish Agency for Science and Higher Education
  • European Commission

Data Provider: Digital Science

LINKS
-

Matching Records in NORA

SUBJECTS
+

METRICS
+