Litcius/Paper detail

A freeze-thaw molten salt battery for seasonal storage

Minyuan M. Li, Xiaowen Zhan, Evgueni Polikarpov, Nathan Canfield, Mark Engelhard, J. Mark Weller, David Reed, Vincent Sprenkle, Guosheng Li

2022Cell Reports Physical Science19 citationsDOIOpen Access PDF

Abstract

Grid-level storage of seasonal excess can be an important asset to renewable electricity. By applying the freeze-thaw thermal cycling strategy, here, we report Al-Ni molten salt batteries with effective capacity recovery over 90% after a period of 1–8 weeks as a proof-of-concept. We explore three activation methods of the nickel cathode in a molten-salt battery: (1) heat treating the cathode granules under H2/N2, (2) incorporating a partially charged NiCl2/Ni cathode, and (3) doping the molten salt electrolyte with sulfur. In particular, sulfur doping, a cost-efficient method suitable for large-scale applications, is not only effective in activating the Ni cathode initially but also invaluable for energy retention during thermal cycling. Overall, these Al-Ni molten salt batteries under thermal cycling show high retention in cell capacity over weeks, setting a direction for scalable seasonal storage.

Topics & Concepts

Molten saltBattery (electricity)CathodeEnergy storageThermal energy storageElectrolyteMaterials scienceRenewable energyTemperature cyclingSalt (chemistry)Chemical engineeringElectrodeThermalChemistryMetallurgyElectrical engineeringMeteorologyEngineeringQuantum mechanicsPower (physics)PhysicsBiologyEcologyPhysical chemistryAdvanced Battery Materials and TechnologiesAdvanced battery technologies researchThermal Expansion and Ionic Conductivity