Jin-Ling Ma

TL;DR: Electrochemical investigations show that stripping and plating of Li and Na and the robust and flexible passivation film formed in situ suppress dendrite and buffer alloy anode volume expansion and thus prevent cracking, avoiding electrolyte consumption and ensuring high electron transport efficiency and continued electrochemical reactions.

TL;DR: Li-N 2 rechargeable batteries have been used for N 2 fixation in this paper, where the authors reported the successful implementation of a reversible N 2 cycle based on a rechargeable lithium-nitrogen battery with the proposed reversible reaction of 6Li+N 2 ⇋ 2Li 3 N.

TL;DR: A well-designed protection layer endows the Li metal anode with dendrite-free plating/stripping and anticorrosion behavior both in ether-based and carbonate ester-based electrolytes.

TL;DR: Li et al. as discussed by the authors proposed and demonstrated a facile and highly efficient strategy for the in situ growth of a self-healing protective film on a lithium metal anode, wherein tetraethyl orthosilicate plays a key role as a novel film-forming electrolyte additive.

TL;DR: In this article, the authors proposed a highly effective strategy to activate and stabilize low cost while inefficient N-doped carbon fibers by in situ simultaneous Co embedding/coating.