Synthesis of the porous spinel Co-Al2O4 powder produced by ball milling and annealing

A. S. Bolokang; R. Modiba; D. E. Motaung; P. E. Ngoepe

doi:10.1016/j.apt.2020.05.003

Synthesis of the porous spinel Co-Al₂O₄ powder produced by ball milling and annealing

A. S. Bolokang, R. Modiba, D. E. Motaung, P. E. Ngoepe

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Ball milling (BM) of elemental Co and Al was conducted for 30 h (h). This process has altered the original morphologies of both elemental Co and Al powders. Spherical Al powder particles has changed into a smooth pancake-shape while the original irregular-shaped Co agglomerates became disintegrated ultrafine particles. BM of the Co20 wt.% Al powder mixture after 30 h yielded thin irregular-shaped particles. XRD analysis revealed a partial structural transformation after BM and further structural change upon annealing the powder at 600 °C, as confirmed by the SEM images. The formation of the cubic spinel superstructure with lattice parameter a = 8.066 Å (ZnAl₂O₄ prototype) and Fd-3 m # 227 space group was realized. By means of LEO 1525 field-emission scanning electron microscope (FE-SEM), a fibrous mesoporous structure was revealed on the milled powder after annealing the Co-Al mixture at 600 °C. The EDS analysis confirmed a minor N impurity on the annealed powder.

Original language	English
Pages (from-to)	2742-2748
Number of pages	7
Journal	Advanced Powder Technology
Volume	31
Issue number	7
DOIs	https://doi.org/10.1016/j.apt.2020.05.003
Publication status	Published - Jul 2020
Externally published	Yes

Keywords

Annealing
Co-Al
Phase transformation
Photoluminescence
Spinel

ASJC Scopus subject areas

General Chemical Engineering
Mechanics of Materials

Access to Document

10.1016/j.apt.2020.05.003

Cite this

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title = "Synthesis of the porous spinel Co-Al2O4 powder produced by ball milling and annealing",

abstract = "Ball milling (BM) of elemental Co and Al was conducted for 30 h (h). This process has altered the original morphologies of both elemental Co and Al powders. Spherical Al powder particles has changed into a smooth pancake-shape while the original irregular-shaped Co agglomerates became disintegrated ultrafine particles. BM of the Co20 wt.% Al powder mixture after 30 h yielded thin irregular-shaped particles. XRD analysis revealed a partial structural transformation after BM and further structural change upon annealing the powder at 600 °C, as confirmed by the SEM images. The formation of the cubic spinel superstructure with lattice parameter a = 8.066 {\AA} (ZnAl2O4 prototype) and Fd-3 m # 227 space group was realized. By means of LEO 1525 field-emission scanning electron microscope (FE-SEM), a fibrous mesoporous structure was revealed on the milled powder after annealing the Co-Al mixture at 600 °C. The EDS analysis confirmed a minor N impurity on the annealed powder.",

keywords = "Annealing, Co-Al, Phase transformation, Photoluminescence, Spinel",

author = "Bolokang, {A. S.} and R. Modiba and Motaung, {D. E.} and Ngoepe, {P. E.}",

note = "Publisher Copyright: {\textcopyright} 2020 Society of Powder Technology Japan",

year = "2020",

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AU - Bolokang, A. S.

AU - Modiba, R.

AU - Motaung, D. E.

AU - Ngoepe, P. E.

PY - 2020/7

Y1 - 2020/7

N2 - Ball milling (BM) of elemental Co and Al was conducted for 30 h (h). This process has altered the original morphologies of both elemental Co and Al powders. Spherical Al powder particles has changed into a smooth pancake-shape while the original irregular-shaped Co agglomerates became disintegrated ultrafine particles. BM of the Co20 wt.% Al powder mixture after 30 h yielded thin irregular-shaped particles. XRD analysis revealed a partial structural transformation after BM and further structural change upon annealing the powder at 600 °C, as confirmed by the SEM images. The formation of the cubic spinel superstructure with lattice parameter a = 8.066 Å (ZnAl2O4 prototype) and Fd-3 m # 227 space group was realized. By means of LEO 1525 field-emission scanning electron microscope (FE-SEM), a fibrous mesoporous structure was revealed on the milled powder after annealing the Co-Al mixture at 600 °C. The EDS analysis confirmed a minor N impurity on the annealed powder.

AB - Ball milling (BM) of elemental Co and Al was conducted for 30 h (h). This process has altered the original morphologies of both elemental Co and Al powders. Spherical Al powder particles has changed into a smooth pancake-shape while the original irregular-shaped Co agglomerates became disintegrated ultrafine particles. BM of the Co20 wt.% Al powder mixture after 30 h yielded thin irregular-shaped particles. XRD analysis revealed a partial structural transformation after BM and further structural change upon annealing the powder at 600 °C, as confirmed by the SEM images. The formation of the cubic spinel superstructure with lattice parameter a = 8.066 Å (ZnAl2O4 prototype) and Fd-3 m # 227 space group was realized. By means of LEO 1525 field-emission scanning electron microscope (FE-SEM), a fibrous mesoporous structure was revealed on the milled powder after annealing the Co-Al mixture at 600 °C. The EDS analysis confirmed a minor N impurity on the annealed powder.

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KW - Co-Al

KW - Phase transformation

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