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Professor Wenbo Liu's Team Has Made Important Progress in the Optimization Design and Performance Improvement of the Electrode Structure of the next Generation of High-Performance Lithium-ion Batteries

Date:Apr 13, 2021

Recently, Professor Wenbo Liu's team from the School of Mechanical Engineering in our school has made important progress in the optimization design and performance improvement of the electrode structure of the next generation of high-performance lithium-ion batteries.“In-situ synthesis of freestanding porous SnOx-decorated Ni3Sn2composites with enhanced Li storage properties” was published in the international authoritative journal in the field of engineering technology Chemical Engineering Journal.

The first author and corresponding author of the paper are both associate professor Wenbo Liu of School of Mechanical Engineering in our school.

In this paper, novel freestanding 3D hierarchical porous SnOx-decorated Ni3Sn2 (3D-HP SnOx@Ni3Sn2) composites are synthesized facilely by two-step chemical dealloying of designed as-cast Sn-45 at.% Ni alloy in different corrosive solutions. The results show that the 3D-HP SnOx@Ni3Sn2 composites have a typical bimodal pore size distribution composed of a micron-sized ligament-channel structure with highly nanoporous channel walls built by ultrafine SnOx (x = 1, 2) nanoparticles (3–6 nm). The unique 3D-HP composites as a binder-free integrated anode for lithium ion batteries (LIBs) display a significantly improved Li storage performance with first reversible capacity of 2.68 mAh cm−2 and good cycling stability with 85.1% capacity retention and over 98.4% coulombic efficiency after 100 cycles (just 0.004 mAh cm2 per cycle for capacity fading). This can be mainly ascribed to the synergistic effect between chemically inert 3D microporous Ni3Sn2 substrate with robust mechanical stress buffer and good transfer mass channels and in-situ growth of nanoporous SnOx with large specific surface areas and high electrochemical active sites. We believe that the present work can offer a promising anode candidate toward advanced LIBs.(Abstract)

Design and forming of 3D-HP SnOx@Ni3Sn2 electrode

Structure characterization of 3D-HP SnOx@Ni3Sn2 electrode

Electrochemical properties of 3D-HP SnOx@Ni3Sn2 electrode

The work was supported by the National Key Research and Development Program of China, the National Natural Science Foundation of China, the Research Grants Council of the Hong Kong Special Administrative Region (RGC) Fund, and the International Science and Technology Innovation Cooperation of Sichuan Province.

Paper link: https://www.sciencedirect.com/science/article/pii/S138589472100190X

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