Layer coupling between solutal and thermal convection in liquid metal batteries

For longer than one decade, liquid metal batteries (LMBs) are developed with the primary aim to provide economic stationary energy storage. Featuring two liquid metal electrodes separated by a molten salt electrolyte, LMBs operate at elevated temperature as simple concentration cells. Therefore, efficient mass transfer is a basic prerequisite for their economic operation. A thorough understanding of the relevant mechanisms cannot be achieved by studying single layers in isolation. With this motivation, the effects of solutal-and thermally-driven flow are studied, as well as the flow coupling between the three liquid layers of the cell. It is shown that solutal convection appears first and thermal convection much later. While the presence of solutal flow depends on the mode of operation (charge or discharge), the occurrence of thermal convection is dictated by the geometry (thickness of layers). The coupling of the flow phenomena between the layers is intriguing: while thermal convection is confined to its area of origin, i.e. the electrolyte, solutal convection is able to drive flow in the positive electrode and in the electrolyte. (c) 2022 Elsevier Ltd. All rights reserved.

Automated summary

Liquid metal batteries (LMBs) are developed for economic stationary energy storage, and the coupling of flow phenomena between the three liquid layers is crucial for their economic operation. Solutal convection appears first, followed by thermal convection, and their occurrence is influenced by the operation mode and geometry. Solutal convection can drive flow in the positive electrode and electrolyte.