Overcoming passivation in rechargeable magnesium batteries: Artificial solid-electrolyte interface for enhanced anode functionality

“…The current optimization strategies for Mg anodes mainly include electrolyte modification, 32–34 constructing the metal–organic skeleton, 35,36 and designing an artificial solid electrolyte interphase (SEI). 37–39 In particular, in recent years, some researchers have modified magnesium anodes by designing artificial SEIs, which can enhance the stability of the anode interface. Li et al 40 added I 2 to the electrolyte to form a MgI 2 -based protective layer on the magnesium anode.…”

High-efficiency electrodeposition of magnesium alloy-based anodes for ultra-stable rechargeable magnesium-ion batteries

“…The current optimization strategies for Mg anodes mainly include electrolyte modification, 32–34 constructing the metal–organic skeleton, 35,36 and designing an artificial solid electrolyte interphase (SEI). 37–39 In particular, in recent years, some researchers have modified magnesium anodes by designing artificial SEIs, which can enhance the stability of the anode interface. Li et al 40 added I 2 to the electrolyte to form a MgI 2 -based protective layer on the magnesium anode.…”

High-efficiency electrodeposition of magnesium alloy-based anodes for ultra-stable rechargeable magnesium-ion batteries

“…Therefore, rechargeable Na-ion batteries (SIBs) and Mg batteries (RMBs) have been considered promising candidates for large-scale energy storage devices. 6–9 However, considering the large ionic radius of Na + and strong polarization of Mg 2+ , anode materials with fast ionic diffusion kinetics for SIBs and RMBs are imperative.…”

Theoretical insights into the intercalation mechanism of Li, Na, and Mg ions in a metallic BN/VS₂ heterostructure

Recent progress of magnesium electrolytes for rechargeable magnesium batteries