MoS2/SnS@C hollow hierarchical nanotubes as superior performance anode for sodium-ion batteries

TL;DR: In this article , two different MoS2•ZnIn2S4 heterointerfaces are designed and fabricated for structural improvement, which generate directional built-in electric fields that provide additional driving forces for electron transfer.

TL;DR: In this article , a multidimensional porous anode for SIBs was constructed by zero-dimensional ultrasmall CoSe2 nanodots confined in one-dimensional porous carbon nanowires and well encapsulated within three-dimensional (3DG/CoSe2@CNWs), which exhibits plentiful reactive sites, interconnected conductive network, abundant ion transport channels, and double protective structure.

TL;DR: Researchers develop a soft-rigid Co9S8@MoS2 core-shell heterostructure with cation vacancies for high-performance sodium-ion batteries, achieving exceptional sodium-storage performance (389.7 mA h g-1) and energy density (235.5 Wh kg-1).

TL;DR: In this paper , unique 2D lamellar VS 2 /MoS 2 heterojunctions boost reaction kinetics of Na + and improve long cycle life for sodium storage, which is useful for long-lived storage.

TL;DR: In this article, a new class of Zn anodes modified by a 3D nanoporous ZnO architecture coating on a Zn plate (designated as Zn@ZnO-3D) was presented.

TL;DR: This review describes some of the exciting progress being made in this area through use of computer simulation techniques, focusing primarily on positive electrode (cathode) materials for lithium- ion batteries, but also including a timely overview of the growing area of new cathode materials for sodium-ion batteries.

TL;DR: Improved extrinsic pseudocapacitive contribution is demonstrated as the origin of fast kinetics of an alloying-based SnS2 electrode and the S-edge effect on the fast Na+ migration and reversible and sensitive structure evolution during high-rate charge/discharge is verified.

TL;DR: The restriction to ultrasmall reaction domains allows for an almost diffusion-less and nucleation-free "conversion" of MoS2 nanodots, thereby resulting in a high capacity and a remarkable cycling performance.