Litcius/Paper detail

A Thin‐Layer, Li<sup>+</sup> Compensation, Moisture‐Tolerant Interfacial Modification of Cu Substrate Toward the Anode‐Less, Energy/Power Dense Li Metallic Batteries

Helin Wang, Yucheng Yuan, Qiurong Jia, Ahu Shao, Min Zhang, Zhiqiao Wang, Cheng Lü, Xiaoyu Tang, Shaowen Li, Yue Ma

2024Advanced Functional Materials20 citationsDOI

Abstract

Abstract The unregulated metallic deposition and continuous cracking of the fragile solid electrolyte interphase are considered the critical barriers that compromise the cyclability of lithium metal batteries (LMB), especially under low N/P ratio (&lt;3) pairing modes. Herein, an ultra‐thin (5 µm), lightweight (0.25 mg cm −2 ), and moisture‐proof interfacial layer composed of the high‐entropy alloys (denoted as HEAs) and interweaved carbon nanotubes (CNTs) scaffold is constructed to modify the current collector, moreover, the thermally‐induced Li 22 Si 5 alloy blended with the hydrophobic ethylene‐vinyl acetate copolymer (EVA) is infiltrated into the scaffold pores as the moisture‐proof cation reservoir. The HEA@CNT/Li 22 Si 5 @EVA interfacial layer not only maximizes the Li‐utilization degree with minimal voltage divergence in symmetric cells but also compensates for irreversible Li depletion in the pouch‐format anode‐less models. As the HEA@CNT/Li 22 Si 5 @EVA‐Cu substrate paired with the LiNi 0.8 Mn 0.1 Co 0.1 O 2 cathode in a 200 mAh prototype, the phase evolution of oxide cathode and efficient Li utilization at the anode substrate can be real‐time monitored by the transmission‐mode operando X‐ray diffraction. This interfacial layer strategy affords multifunctionality to enable the LMB prototyping without excessive Li abuse. Consequently, cycling endurance and the balanced energy densities (420.1 Wh kg −1 ) are obtained on the whole cell.

Topics & Concepts

Materials scienceAnodeCathodeChemical engineeringElectrolyteSubstrate (aquarium)Composite materialNanotechnologyElectrodeEngineeringPhysical chemistryGeologyChemistryOceanographyAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research
A Thin‐Layer, Li<sup>+</sup> Compensation, Moisture‐Tolerant Interfacial Modification of Cu Substrate Toward the Anode‐Less, Energy/Power Dense Li Metallic Batteries | Litcius