Elastic Na<sub><i>x</i></sub>MoS<sub>2</sub>-Carbon-BASE Triple Interface Direct Robust Solid–Solid Interface for All-Solid-State Na–S Batteries
Ke Lu, Bomin Li, Xiaowen Zhan, Fan Xia, Olusola John Dahunsi, Siyuan Gao, David Reed, Vincent Sprenkle, Guosheng Li, Yingwen Cheng
Abstract
The developments of all-solid-state sodium batteries are severely constrained by poor Na-ion transport across incompatible solid–solid interfaces. We demonstrate here a triple NaxMoS2-carbon-BASE nanojunction interface strategy to address this challenge using the β″-Al2O3 solid electrolyte (BASE). Such an interface was constructed by adhering ternary Na electrodes containing 3 wt % MoS2 and 3 wt % carbon on BASE and reducing contact angles of molten Na to ∼45°. The ternary Na electrodes exhibited twice improved elasticity for flexible deformation and intimate solid contact, whereas NaxMoS2 and carbon synergistically provide durable ionic/electronic diffusion paths, which effectively resist premature interface failure due to loss of contact and improved Na stripping utilization to over 90%. Na metal hosted via triple junctions exhibited much smaller charge-transfer resistance and 200 h of stable cycling. The novel interface architecture enabled 1100 mAh/g cycling of all-solid-state Na–S batteries when using advanced sulfur cathodes with Na-ion conductive PEO10-NaFSI binder and NaxMo6S8 redox catalytic mediator.