Free-Standing Stable Silicon-Based Anode with Exceptional Flexibility Realized by a Multifunctional Structure Design in Multiple Dimensions.

Cyclized polyacrylonitrile (cPAN) with decently flexible, elastic, and conductive properties is a promising substrate or binder material for flexible devices. However, it is infeasible to accommodate the large volume expansion and contribute the exceptional rate capability of silicon anodes in lithium-ion batteries only counting on the limited elasticity and conductivity of cPAN. Herein, we report a robust silicon/carbon-cPAN-graphene (SC-CP-G) composite membrane with excellent flexibility based on a multifunctional structure design in multiple dimensions, which can be used as a free-standing integrated anode for lithium ion batteries.

Gradient Structure Design of a Floatable Host for Preferential Lithium Deposition.

Herein, a novel sandwichlike host with expandable accommodation and gradient characteristics of lithiophilicity and conductivity is prepared by constructing a reduced graphene oxide (rGO)/SiO/rGO intercalated structure on the basis of electrospraying and coating an additional PVDF-HFP layer on the top surface. This gradient host electrode enables preferential, ordered, and uniform Li deposition in the SiO-embedded interlayer space. The dendrite growth and isolated Li are suppressed by the combined rGO/PVDF-HFP layer with robust, flexible, and floatable features, which could function as an artificial solid-electrolyte interphase to impede reckless electrolyte infiltration, homogenize the Li ion flux distribution, and build a stable electrochemical interface.