Operando Methods and Probes for Battery Electrodes and Materials

TL;DR

This paper reviews advanced non-destructive operando techniques like optical spectroscopies and microscopy that are crucial for understanding real-time processes in battery electrodes and materials, aiding development of better batteries.

Contribution

It provides a comprehensive overview of recent operando methods and probes used to analyze battery materials, interfaces, and reactions in real-time under working conditions.

Findings

Optical spectroscopies reveal dynamic processes in battery electrodes.

Synchrotron radiation techniques provide detailed internal insights.

Atom probe tomography offers atomic-scale analysis of battery interfaces.

Abstract

With the importance of Li-ion and emerging alternative batteries to our electric future, predicting new sustainable materials, electrolytes and complete cells that safely provide high performance, long life, energy dense capability is critically important. Understanding interface, microstructure of materials, the nature of electrolytes and factors that affect or limit long term performance are key to new battery chemistries, cell form factors and alternative materials. The electrochemical processes which cause these changes are also difficult to probe because of their metastability and lifetimes, which can be of nanosecond to sub nanosecond time domains. Consequently, developing and adapting high-resolution, non-destructive methods to capture these processes proves challenging, requiring state-of-the-art techniques.Recent progress is very promising, where optical spectroscopies, synchrotron radiation techniques, and energy-specific atom probe tomography and microscopy methods are just some of the approaches that are unravelling the true internal behaviour of battery cells in real-time.In this review, we overview many of the most promising non-destructive methods developed in recent years to assess battery material properties, interfaces, processes,and reactions under operando conditions in electrodes and full cells.