金属钠原位镀钴金属钠电池

arXiv: Chemical Physics Pub Date : 2018-10-02 DOI:10.13140/RG.2.2.15903.20646

Saurav L. Chaudhari, Ketan P Pise

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摘要

在这项工作中，我们证明了钠化学的能量密度可以通过使用铝集流器上形成的(纳米碳/钴氧化物)成核层实现无阳极结构来实现。电化学研究表明，这种配置可以在高达5 mA/cm2的电流范围内提供高度稳定和高效的镀和剥离钠金属，钠负载高达14 mAh/cm2，并且在0.7 mA/cm2的电流下具有超过1000次的长期耐用性。在这种无阳极结构的基础上，我们展示了一个使用沉淀的黄铁矿阴极的完整电池，其能量密度达到400 Wh/kg，远远超过了最近关于sib的报道，甚至是LIB技术的理论最大值，同时仍然依赖于天然丰富的原材料和具有成本效益的水处理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Sodium Metal Battery using CobaltOxide through in Situ Plating of Sodium Metal

In this work, we demonstrate that an impugn of energy density for sodium chemistries can be prevail through an anode-free architecture enabled by the use of a (nanocarbon/Cobaltoxide) nucleation layer formed on Aluminium current collectors. Electrochemical studies show this configuration to provide highly stable and efficient plating and stripping of sodium metal over a range of currents up to 5 mA/cm2, sodium loading up to 14 mAh/cm2, and with long-term endurance exceeding 1000 cycles at a current of 0.7 mA/cm2. Building upon this anode-free architecture, we demonstrate a full cell using a presodiated pyrite cathode to achieve energy densities of 400 Wh/kg, far surpassing recent reports on SIBs and even the theoretical maximum for LIB technology while still relying on naturally abundant raw materials and cost-effective aqueous processing.

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arXiv: Chemical Physics

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