A Deeper Understanding of Metal Nucleation and Growth in Rechargeable Metal Batteries Through Theory and Experiment

Lithium and sodium metal batteries continue to occupy the forefront of battery research. Their exceptionally high energy density and nominal voltages are highly attractive for cutting-edge energy storage applications. Anode-free metal batteries are also coming into the research spotlight offering improved safety and even higher energy densities than conventional metal batteries. However, uneven metal nucleation and growth which leads to dendrites continues to limit the commercialisation of conventional and anode-free metal batteries alike. This review connects models and theories from well-established fields in metallurgy and electrodeposition to both conventional and anode-free metal batteries. These highly applicable models and theories explain the driving forces of uneven metal growth and can inform future experiment design. Finally, the models and theories that are most relevant to each anode-related cell component are identified. Keeping these specific models and theories in mind will assist with rational design for these components. Rechargeable metal batteries are still at the forefront of battery research. Each battery cell component that relates to anode performance (the current collector, anode surface, solid-electrolyte interphase (SEI), and electrolyte) is described by a unique set of applicable models and theories to better understand and predict metal nucleation and growth.image

Automated summary

Lithium and sodium metal batteries, as well as anode-free metal batteries, are important in battery research due to their high energy density. However, the uneven metal nucleation and growth hinder their commercialization. This review connects models and theories from metallurgy and electrodeposition to explain the driving forces behind uneven metal growth and provide guidance for future experiment design.