Litcius/Paper detail

Tuning the electron transport behavior at Li/LATP interface for enhanced cyclability of solid-state Li batteries

Linshan Luo, Feng Zheng, Haowen Gao, Chaofei Lan, Zhefei Sun, Wei Huang, Xiang Han, Ziqi Zhang, Pengfei Su, Peng Wang, Shengshi Guo, Guangyang Lin, Jianfang Xu, Jianyuan Wang, Jun Li, Cheng Li, Qiaobao Zhang, Shunqing Wu, Ming‐Sheng Wang, Songyan Chen

2022Nano Research38 citationsDOI

Abstract

An interlayer is usually employed to tackle the interfacial instability issue between solid electrolytes (SEs) and Li metal caused by the side reaction. However, the failure mechanism of the ionic conductor interlayers, especially the influence from electron penetration, remains largely unknown. Herein, using Li1.3Al0.3Ti1.7(PO4)3 (LATP) as the model SE and LiF as the interlayer, we use metal semiconductor contact barrier theory to reveal the failure origin of Li/LiF@LATP interface based on the calculation results of density functional theory (DFT), in which electrons can easily tunnel through the LiF grain boundary with F vacancies due to its narrow barrier width against electron injection, followed by the reduction of LATP. Remarkably, an Al-LiF bilayer between Li/LATP is found to dramatically promote the interfacial stability, due to the highly increased barrier width and homogenized electric field at the interface. Consequently, the Li symmetric cells with Al-LiF bilayer can exhibit excellent cyclability of more than 2,000 h superior to that interlayered by LiF monolayer (∼ 860 h). Moreover, the Li/Al-LiF@LATP/LiFePO4 solid-state batteries deliver a capacity retention of 83.2% after 350 cycles at 0.5 C. Our findings emphasize the importance of tuning the electron transport behavior by optimizing the potential barrier for the interface design in high-performance solid-state batteries.

Topics & Concepts

Materials scienceDensity functional theoryGrain boundaryElectrolyteElectronIonic bondingChemical physicsBilayerCondensed matter physicsChemical engineeringChemistryIonElectrodeComposite materialPhysical chemistryComputational chemistryMicrostructureMembraneBiochemistryEngineeringPhysicsQuantum mechanicsOrganic chemistryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research