Surface halogenation engineering for reversible silicon-based solid-state batteries
Haosheng Li, Yaru Li, Guantai Hu, Ying Li, Caijin Xiao, Liang Zhao, Huiqin Huang, Haochang Zhang, Wei Xia, Ning Lin
Abstract
Silicon-based solid-state batteries are promising next-generation high-energy-density technologies. However, poor (electro)chemical compatibility between silicon negative electrodes and solid electrolytes (e.g., Li6PS5Cl) plus sluggish interfacial kinetics severely limits their reversibility and Coulombic efficiency. Here, we propose a surface halogenation strategy that transforms the native amorphous SiO2 passivation layer on silicon particles into a functional Al(Si)OCl composite surface via controlled reaction with AlCl3. This artificial interphase reconciles interfacial incompatibility and enables fast ionic/electronic transport, suppressing irreversible lithium loss. The optimized negative electrode achieves a high initial Coulombic efficiency of 94.3% in half-cells and 85.6% initial Coulombic efficiency (86.6% with pre-lithiation) in full cells paired with LiNi0.88Co0.09Mn0.03O2. Enhanced reversibility further delivers long-term cyclability. The optimized negative electrode delivers 86% capacity retention and 99.998% average Coulombic efficiency over 200 cycles. Even at high-loading ( > 10 mAh cm-2, and no adhesives/conductive carbon/electrolyte), it retains 72% capacity after 500 cycles. The full cells maintain 80% capacity after 200 cycles at 1 C, with an average Coulombic efficiency exceeding 99.95%. The versatility of this halogenation strategy underscores halide chemistry’s broad potential in advancing high-performance, reversible silicon-based solid-state batteries. Silicon negative electrodes in solid-state batteries exhibit poor reversibility. Here, the authors demonstrate surface halogenation engineering that suppresses irreversible lithium loss, achieving 94.3% initial Coulombic efficiency and 72% capacity retention over 500 cycles at 25°C.