Thermally-treated nanowire-structured stainless-steel as an attractive cathode material for lithium-ion batteries.

A novel 3D composite cathode structure, comprised of MnCr 2 O 4 spinel-based nanowires, is hereby presented. The reagentless self-seeded spinel-based nanowires are synthesized using an extremely simple, one-step, growth process that is comprised of 5% hydrogen in nitrogen at atmospheric pressure, under 1100 °C , without any external catalyst or reagent. This simple one-step process allows the density-controlled growth of highly crystalline spinel nanowires directly from common stainless steel mesh substrates, which acts both as reagents source and as a current collector. Electrochemical measurements show that this cathode exhibits high capacity (>230 mA h/g), stable cyclability (>370 cycles), high coulombic efficiency (>99%) and high rate performance (>2C). The novel 3D composite cathode structure exhibits several major advantages over conventional 2D cathodes, both in terms of the synthesis process, cost-effectiveness and in terms of electrochemical performance enhancement possibilities. Image 1 • A novel 3D composite cathode structure, comprised of MnCr 2 O 4 spinel-based nanowires, is hereby presented. • The self-seeded spinel-based nanowires are grown by an extremely simple, one-step, growth process, without any external catalyst or reagent. • Cathodes exhibit high capacity (> 230 mAh/g), high cyclability (> 360 cycles), high coulombic efficiency (> 99%) and high rate performance (> 2C). • The 3D-cathode exhibits several major advantages over conventional 2D cathodes in terms of the synthesis, cost and electrochemical performance. [ABSTRACT FROM AUTHOR]