Dendrite Suppression by Shock Electrodeposition in Charged Porous Media

TL;DR

This paper demonstrates that shock electrodeposition in charged porous media can stabilize metal growth at high rates, suppressing dendrites and potentially improving battery cycle life and manufacturing processes.

Contribution

It reveals that transient electro-diffusion and deionization shocks can stabilize electrodeposition in random porous media, challenging classical models.

Findings

Surface conduction stabilizes growth in negative separators.

Dendrite suppression improves cycle life.

Irregular growth occurs in positive separators.

Abstract

It is shown that surface conduction can stabilize electrodeposition in random, charged porous media at high rates, above the diffusion-limited current. After linear sweep voltammetry and impedance spectroscopy, copper electrodeposits are visualized by scanning electron microscopy and energy dispersive spectroscopy in two different porous separators (cellulose nitrate, polyethylene), whose surfaces are modified by layer-by-layer deposition of positive or negative charged polyelectrolytes. Above the limiting current, surface conduction inhibits growth in the positive separators and produces irregular dendrites, while it enhances growth and suppresses dendrites behind a deionization shock in the negative separators, also leading to improved cycle life. The discovery of stable uniform growth in the random media differs from the non-uniform growth observed in parallel nanopores and cannot be explained by classical quasi-steady leaky membrane models, which always predict instability and dendritic growth. Instead, the experimental results suggest that transient electro-diffusion in random porous media imparts the stability of a deionization shock to the growing metal interface behind it. Shock electrodeposition could be exploited to enhance the cycle life and recharging rate of metal batteries or to accelerate the fabrication of metal matrix composite coatings.