Topology-enhanced mechanical stability of swelling nanoporous electrodes

Materials like silicon and germanium offer a 10-fold improvement in charge capacity over conventional graphite anodes in lithium-ion batteries but experience a roughly threefold volume increase during lithiation, which challenges ensuring battery integrity. Nanoporous silicon, created by liquid-metal-dealloying, is a potentially attractive anode design to mitigate this challenge, exhibiting both higher capacity and extended cycle lifetimes. However, how nanoporous structures accommodate the large volume change is unknown. Here, we address this question by using phase-field modeling to produce nanoporous particles and to investigate their elastoplastic swelling behavior and fracture. Our simulations show that enhanced mechanical stability results from the network topology consisting of ligaments connected by bulbous, sphere-like nodes. The ligaments forcefully resist elongation while the nodes, behaving like isolated spherical particles, experience large stresses driving fracture. However, being smaller compared to a sphere of the same volume as the entire nanoporous particle, the nodes are more protected against fracture.

Automated summary

Nanoporous silicon, created by liquid-metal-dealloying, exhibits higher capacity and extended cycle lifetimes in lithium-ion batteries. Using phase-field modeling, we investigate the elastoplastic swelling behavior and fracture of these nanoporous particles. Our simulations show that the network topology consisting of ligaments connected by bulbous, sphere-like nodes enhances mechanical stability.