Silicon‐based anode has high theoretical capacity but suffers from poor electrical
conductivity, large volume expansion, and unstable solid electrolyte interphase (SEI) …

Li‐ion batteries are essential technologies for electronic products in the daily life. However,
serious fire safety concerns that are closely associated with the flammable liquid electrolyte …

Micro-sized alloying anodes offer lower cost and higher capacity than graphite in Li-ion
batteries. However, they suffer from fast capacity decay and low Coulombic efficiency in …

The practical application of silicon (Si) anodes in the next-generation high-energy lithium-
ion batteries (LIBs) is largely hindered by their capacity loss due to the formation of a solid …

Silicon suboxides (SiOx) materials are highly desirable as anode for high energy Li‐ion
batteries due to their much higher specific capacity than conventional graphite anode …

In the quest for high-capacity battery electrodes, addressing capacity loss attributed to
isolated active materials remains a challenge. We developed an approach to substantially …

The silicon‐based anodes are one of the promising anodes to achieve the high energy
density of all‐solid‐state batteries (ASSBs). Nano silicon (nSi) is considered as a suitable …

Unlike most anodes used in high energy density batteries, lithiated Si does not form long-
lasting passivating solid-electrolyte interphases (SEI) during formation or on charge due to …

Deleterious volumetric expansion and poor electrical conductivity seriously hinder the
application of Si-based anode materials in lithium-ion batteries (LIBs). Herein, boron-doped …

Compared to lithium (Li) anode, the alloy/Li‐alloy anodes show more compatible with sulfide
solid electrolytes (SSEs), and are promising candidates for practical SSE‐based all‐solid …