Extremely High Surface Area Metallurgical-Grade Porous Silicon Powder Prepared by Metal-Assisted Etching

A Loni; D Barwick; L Batchelor; J Tunbridge; Yisong Han; Zi Li; LT Canham

doi:10.1149/1.3548513

Extremely High Surface Area Metallurgical-Grade Porous Silicon Powder Prepared by Metal-Assisted Etching

A Loni, D Barwick, L Batchelor, J Tunbridge, Yisong Han, Zi Li, LT Canham

Physics and Astronomy

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49 Citations (Scopus)

Abstract

Metallurgical-grade silicon powder (10 m(2)/g surface area) has been porosified using a metal-assisted chemical etch process based on hydrofluoric acid-ferric chloride chemistry. By controlling the reagent concentrations and ratios, the degree of porosification has been varied. Initiating the reaction at temperatures below 0 degrees C, typically between -15 degrees C and -25 degrees C, yields etched powders with spectacularly increased surface area and pore volume (porosity). The reduced temperature, and its subsequent control, favors pore nucleation and propagation while minimizing bulk chemical etching. Using this process, mesoporous powders with surface areas up to 480 m(2)/g and pore volumes up to 0.52 ml/g have proved easily achievable at the 10 g batch level. (C) 2011 The Electrochemical Society. [DOI: 10.1149/1.3548513] All rights reserved.

Original language	English
Pages (from-to)	K25-K27
Journal	Electrochemical and Solid-State Letters
Volume	14
Issue number	5
DOIs	https://doi.org/10.1149/1.3548513
Publication status	Published - 1 Jan 2011

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10.1149/1.3548513

Towards an Atomic-scale understanding of the 3D Structures of size-selected Clusters on Surfaces
Li, Z., Johnston, R. & Palmer, R.
Engineering & Physical Science Research Council
1/02/10 → 17/01/14
Project: Research Councils

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title = "Extremely High Surface Area Metallurgical-Grade Porous Silicon Powder Prepared by Metal-Assisted Etching",

abstract = "Metallurgical-grade silicon powder (10 m(2)/g surface area) has been porosified using a metal-assisted chemical etch process based on hydrofluoric acid-ferric chloride chemistry. By controlling the reagent concentrations and ratios, the degree of porosification has been varied. Initiating the reaction at temperatures below 0 degrees C, typically between -15 degrees C and -25 degrees C, yields etched powders with spectacularly increased surface area and pore volume (porosity). The reduced temperature, and its subsequent control, favors pore nucleation and propagation while minimizing bulk chemical etching. Using this process, mesoporous powders with surface areas up to 480 m(2)/g and pore volumes up to 0.52 ml/g have proved easily achievable at the 10 g batch level. (C) 2011 The Electrochemical Society. [DOI: 10.1149/1.3548513] All rights reserved.",

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AU - Loni, A

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AU - Tunbridge, J

AU - Han, Yisong

AU - Li, Zi

AU - Canham, LT

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N2 - Metallurgical-grade silicon powder (10 m(2)/g surface area) has been porosified using a metal-assisted chemical etch process based on hydrofluoric acid-ferric chloride chemistry. By controlling the reagent concentrations and ratios, the degree of porosification has been varied. Initiating the reaction at temperatures below 0 degrees C, typically between -15 degrees C and -25 degrees C, yields etched powders with spectacularly increased surface area and pore volume (porosity). The reduced temperature, and its subsequent control, favors pore nucleation and propagation while minimizing bulk chemical etching. Using this process, mesoporous powders with surface areas up to 480 m(2)/g and pore volumes up to 0.52 ml/g have proved easily achievable at the 10 g batch level. (C) 2011 The Electrochemical Society. [DOI: 10.1149/1.3548513] All rights reserved.

AB - Metallurgical-grade silicon powder (10 m(2)/g surface area) has been porosified using a metal-assisted chemical etch process based on hydrofluoric acid-ferric chloride chemistry. By controlling the reagent concentrations and ratios, the degree of porosification has been varied. Initiating the reaction at temperatures below 0 degrees C, typically between -15 degrees C and -25 degrees C, yields etched powders with spectacularly increased surface area and pore volume (porosity). The reduced temperature, and its subsequent control, favors pore nucleation and propagation while minimizing bulk chemical etching. Using this process, mesoporous powders with surface areas up to 480 m(2)/g and pore volumes up to 0.52 ml/g have proved easily achievable at the 10 g batch level. (C) 2011 The Electrochemical Society. [DOI: 10.1149/1.3548513] All rights reserved.

U2 - 10.1149/1.3548513

DO - 10.1149/1.3548513

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JO - Electrochemical and Solid-State Letters

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Extremely High Surface Area Metallurgical-Grade Porous Silicon Powder Prepared by Metal-Assisted Etching

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Towards an Atomic-scale understanding of the 3D Structures of size-selected Clusters on Surfaces

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