An operando calorimeter for high temperature electrochemical cells

TL;DR

This paper introduces a novel operando calorimeter capable of high temperature operation up to 1,000°C, enabling simultaneous calorimetry and electrochemistry for advanced study of electrochemical cells in extreme conditions.

Contribution

The paper presents a new high-temperature operando calorimeter design that can operate up to 1,000°C and analyze thermal and electrochemical behavior simultaneously.

Findings

Achieved a power sensitivity of 16.1 ± 11.7 mW.

Modified a commercial apparatus for high temperature electrochemical studies.

Enabled analysis of thermal and kinetic behavior at elevated temperatures.

Abstract

Operando calorimetry has previously been utilized to study degradation, side reactions, and other electrochemical effects in electrochemical cells such as batteries at or near room temperature. Calorimetric data can provide important information on the lifetime and thermal properties of electrochemical cells and can be used in practical engineering applications such as thermal management. High temperature electrochemical cells such as solid oxide fuel cells or electrolyzers can also benefit from operando calorimetry, although to our knowledge no such unit has been developed commercially. Herein, we report an operando calorimeter capable of simultaneous calorimetry and electrochemistry at temperatures up to 1,000 {\deg}C and in both oxidizing and reducing atmospheres. The calorimeter is constructed by modifying a commercial apparatus originally designed to study high temperature electrochemical cells in various gas environments. We utilize a grey-box, nonlinear system identification model to analyze calorimetric data and achieve an electrochemical cell power sensitivity of 16.1 +/- 11.7 mW. This operando calorimeter provides the tools needed to study both the thermal and kinetic behavior of electrochemical cells at elevated temperatures.