Dual-gradient metal layer for practicalizing high-energy lithium batteries
Mengyu Tian, Ronghan Qiao, Guanjun Cen, Tian Li, Liubin Ben, Hailong Yu, Michaël De Volder, Chenglong Zhao, Qidi Wang, Xuejie Huang
Abstract
Pairing high-energy nickel-rich cathodes with current collectors as anodes presents a compelling strategy to significantly boost the specific energy of rechargeable lithium-ion batteries, driving progress toward a transportation revolution. However, the limited active lithium inventory sourced by the cathodes tend to be rapidly consumed by irreversible Li plating/stripping and interfacial side reactions. To address these limitations, we propose a dual-gradient metal layer as an innovative solution to mitigate active Li loss by promoting uniform Li deposition and in situ formation of a stable solid electrolyte interphase. The operation of these batteries is investigated using a combination of electrochemical and chemical techniques to differentiate dead Li and interphase-bound Li inventory loss as well as material characterization methods to analyse the plated Li and interfacial composition and morphology. The developed dual gradient metal layer-based 600 mAh LiNi0.9Co0.05Mn0.05O2 | |Cu pouch cells achieve an areal capacity of 7.25 mAh cm−2 and deliver an 80% capacity retention over 160 cycles. We show that the proposed approach is compatible with a range of different metal materials, offering a promising path toward next generation long-lasting, high-energy, initially active material-free anode based Li metal batteries. Anode-free Li metal batteries suffer from irreversible Li plating/stripping and interfacial side reactions. Here, authors propose a dual-gradient metal layer on Cu current collector to promote uniform Li deposition and the in situ formation of a stable solid electrolyte interphase.