Affiliation:
1. Institute of Chemistry St. Petersburg University St. Petersburg Universitetskaya Emb.7/9 199034 Russia
2. Institute for Electrophysics and Electrical Power of the Russian Academy of Sciences Dvortsovaya Naberezhnaya 18 St. Petersburg 191186 Russia
3. Department of Materials Science and Engineering University of Virginia Charlottesville, VA 22904, USA
Abstract
AbstractPursuing of straightforward and cost‐effective methods for synthesizing high‐performance anode materials for lithium‐ion batteries is a topic of significant interest. This study elucidates a one‐step synthesis approach for a conversion composite using glow discharge in a nickel formate solution, yielding a composite precursor comprising metallic nickel, nickel hydroxide, and basic nickel salts. Subsequent annealing of the precursor facilitated the formation of the Ni@NiO composite, exhibiting exceptional electrochemical properties as anode material in Li‐ion batteries: a capacity of approximately 1000 mAh g−1, cyclic stability exceeding 100 cycles, and favorable rate performance (200 mAh g−1 at 10 A g<M−.1). Comparative analysis across various methods for synthesizing NiO‐based materials underscored the superiority of the Ni@NiO composite. Furthermore, an assessment of resource costs demonstrated the cost‐effectiveness and scalability of the approach in terms of resource consumption per Ah. Lastly, the integration of a Ni@NiO anode with an NMC532 cathode in a full battery highlights Ni@NiO's potential for conversion anodes, achieving a practical gravimetric energy density of 92 Wh kg−1.
Funder
Russian Foundation for Basic Research