Physicochemical Dual Cross-Linking Conductive Polymeric Networks Combining High Strength and High Toughness Enable Stable Operation of Silicon Microparticle Anodes

The poor interfacial stability and insufficient cycling performance caused by undesirable stress hinder the commercial application of silicon microparticles (mu Si) as next-generation anode materials for high-energy-density lithium-ion batteries. Herein, a conceptionally novel physicochemical dual cross-linking conductive polymeric network is designed combining high strength and high toughness by coupling the stiffness of poly(acrylic acid) and the softness of carboxyl nitrile rubber, which includes multiple H-bonds, by introducing highly branched tannic acid as a physical cross-linker. Such a design enables effective stress dissipation by folded molecular chains slipping and sequential cleavage of H-bonds, thus stabilizing the electrode interface and enhancing cycle stability. As expected, the resultant electrode (mu Si/PTBR) delivers an unprecedented high capacity retention of approximate to 97% from 2027.9 mAh g(-1) at the 19th to 1968.0 mAh g(-1) at the 200th cycle at 2 A g(-1). Meanwhile, this unique stress dissipation strategy is also suitable for stabilizing SiOx anodes with a much lower capacity loss of approximate to 0.012% per cycle over 1000 cycles at 1.5 A g(-1). Atomic force microscopy analysis and finite element simulations reveal the excellent stress-distribution ability of the physicochemical dual cross-linking conductive polymeric network. This work provides an efficient energy-dissipation strategy toward practical high-capacity anodes for energy-dense batteries.

Automated summary

A physicochemical dual cross-linking conductive polymeric network is designed to address the poor stability and cycling performance of silicon microparticles as anode materials for lithium-ion batteries. This network enables stress dissipation and enhances the electrode interface stability through folded molecular chains slipping and sequential cleavage of H-bonds. The resulting electrode demonstrates high capacity retention and low capacity loss, making it a promising strategy for practical high-capacity anodes in energy-dense batteries.