Beyond Macroscopic Performance: Nanoscale Charge Transfer Dynamic in Energy Storage/Conversion Device via Scanning Electrochemical Cell Microscopy

Abstract

The performance of electrochemical energy storage and conversion devices is fundamentally governed by nanoscale charge transfer dynamics at buried interfaces, which remain elusive to conventional macroscopic characterization techniques. Scanning electrochemical cell microscopy (SECCM) uniquely combines single-point probing with areal scanning to resolve localized electrochemical activity and bulk-scale architectural evolution, enabling cross-scale correlations between nanoscale charge transfer processes (<100 nm resolution) and macroscale electrode behavior (>100 μm). This capability establishes SECCM as a transformative tool for operando interrogation of interfacial phenomena, including metal ion deposition/insertion, stripping/extraction, and the distribution of active sites in electrocatalysts and the mechanism of degradation-induced failure, with millisecond temporal resolution. This review highlights recent advances in nanoscale charge transfer dynamics, focusing on energy storage material interfaces and electrochemical reaction mechanisms. Finally, we discuss emerging directions for SECCM, including operando visualization of multivalent metal dissolution/deposition (Li/Na/Zn anodes, Li-S conversion interfaces) and atomic-scale tracking of solid-state electrolyte degradation, particularly when integrated with machine learning, to accelerate the commercialization of next-generation sustainable energy technologies.