熔盐中由二氧化硅介导的硅酸电解制备硅纳米管

Silicate-Mediated Electrolytic Silicon Nanotube from Silica in Molten Salts.

作者信息

Jing Shuangxi, Xiao Juanxiu, Shen Yijun, Hong Biao, Gu Dong, Xiao Wei

机构信息

College of Chemistry and Molecular Sciences, Hubei Key Laboratory of Electrochemical Power Sources, Wuhan University, Wuhan, 430072, P. R. China.

State Key Laboratory of Marine Resource Utilization in South China Sea, Hainan University, Haikou, 570228, P. R. China.

出版信息

Small. 2022 Sep;18(35):e2203251. doi: 10.1002/smll.202203251. Epub 2022 Aug 7.

DOI:10.1002/smll.202203251

PMID:35934894

Abstract

Electrochemical preparation/processing of functional silicon from abundant silica is an ideal protocol to promote sustainability of energy sectors. Such an imperative task is challenged by poor electrical conductivity of Si/SiO and inadequate mass diffusion of bulk silicon. Herein, a template-free and one-step preparation of silicon nanotubes (Si-NT) from electrochemical reduction of silica in molten salts is reported. An in situ oriented growth of silicate nanorods (NRs) from silica is clarified as the key step to direct a self-template evolution of Si-NT from silica. The silicate-mediated construction of Si-based NT is versatile and successfully extended to prepare Si-NT/graphite and Ti Si -NT. Benefitting from fast longitudinal motorways for fast transport of electrons and ions along/inside NTs, an energy consumption 30% lower than industrial silicon production is achieved. When evaluated as anode of lithium ion battery, the Si-NT-based electrodes show outstanding initial Coulombic efficiency and high reversible capacity. The silicate-mediated construction of Si-based NT integrates straightforward preparation and intriguing functionality of Si-based materials, bridging a closed-loop Si-based energy infrastructure.

摘要

通过丰富的二氧化硅进行电化学制备/处理功能硅是促进能源领域可持续发展的理想方案。然而，硅/二氧化硅的低电导率和块状硅的质量扩散不足对这一紧迫任务构成了挑战。在此，报道了一种在熔盐中通过电化学还原二氧化硅无模板一步制备硅纳米管（Si-NT）的方法。阐明了从二氧化硅原位生长硅酸盐纳米棒（NRs）是引导二氧化硅自模板演化为Si-NT的关键步骤。硅酸盐介导的硅基纳米管构建具有通用性，并成功扩展到制备Si-NT/石墨和TiSi-NT。受益于沿纳米管/纳米管内部快速传输电子和离子的快速纵向通道，实现了比工业硅生产低30%的能耗。当作为锂离子电池的阳极进行评估时，基于Si-NT的电极表现出出色的初始库仑效率和高可逆容量。硅酸盐介导的硅基纳米管构建整合了硅基材料的直接制备和有趣功能，架起了一个闭环硅基能源基础设施的桥梁。

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熔盐中由二氧化硅介导的硅酸电解制备硅纳米管

Silicate-Mediated Electrolytic Silicon Nanotube from Silica in Molten Salts.

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