Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)

Cobalt oxide (CoO) has been widely studied for photocatalyst of water splitting and displaying a high-efficiency material. This paper reports a Density Functional Theory (DFT) study on the electronic properties of rock-salt CoO and analyzes effects of cations (Ni and Fe) and anions (N and F) dopan...

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Main Authors:	Siti Nurul Falaein Moridon, Khuzaimah Arifin, Amilia Linggawati, Lorna Jeffery Minggu, Mohammad Kassim
Format:	Article
Language:	English
Published:	Penerbit Universiti Kebangsaan Malaysia 2020
Online Access:	http://journalarticle.ukm.my/14843/1/08.pdf http://journalarticle.ukm.my/14843/ http://www.ukm.my/jkukm/volume-321-2020/
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Institution:	Universiti Kebangsaan Malaysia
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spelling	my-ukm.journal.148432020-07-10T08:26:26Z http://journalarticle.ukm.my/14843/ Density functional theory study on the electronic properties of doped-cobalt oxide (CoO) Siti Nurul Falaein Moridon, Khuzaimah Arifin, Amilia Linggawati, Lorna Jeffery Minggu, Mohammad Kassim, Cobalt oxide (CoO) has been widely studied for photocatalyst of water splitting and displaying a high-efficiency material. This paper reports a Density Functional Theory (DFT) study on the electronic properties of rock-salt CoO and analyzes effects of cations (Ni and Fe) and anions (N and F) dopants on the electronic properties. For this purpose, CASTEP software used for first principles plane-wave pseudo-potential calculations at different functional, i.e: GGA-PW91 and LDA. The electronic calculations of the CoO optimized structure showed a metallic structure if without considering spin-orbital interactions. After considering the spin-orbital interaction calculation, the CoO band structure possessed indirect and direct band gaps. The direct bandgap by GGA-PW91 calculation is 2.10 eV, it was agreed to the experimentally reported value of approximately 1.9-2.6 eV. Meanwhile, Ni, Fe, and F-doped CoO, demonstrating decreased CoO direct band gaps to 1.70 eV, 1.80 eV, and 1.73 eV, respectively. While N-doped CoO increased the CoO direct bandgap to 3.05 eV. All dopants shifted the conduction and valence bands position, where Ni-doped CoO band edges keep straddle to the redox potential of water splitting. Among other elements in this study, Ni is a more desirable dopant of CoO to enhance photoelectrochemical hydrogen production. Penerbit Universiti Kebangsaan Malaysia 2020-02 Article PeerReviewed application/pdf en http://journalarticle.ukm.my/14843/1/08.pdf Siti Nurul Falaein Moridon, and Khuzaimah Arifin, and Amilia Linggawati, and Lorna Jeffery Minggu, and Mohammad Kassim, (2020) Density functional theory study on the electronic properties of doped-cobalt oxide (CoO). Jurnal Kejuruteraan, 32 (1). pp. 61-66. ISSN 0128-0198 http://www.ukm.my/jkukm/volume-321-2020/
institution	Universiti Kebangsaan Malaysia
building	Tun Sri Lanang Library
collection	Institutional Repository
continent	Asia
country	Malaysia
content_provider	Universiti Kebangsaan Malaysia
content_source	UKM Journal Article Repository
url_provider	http://journalarticle.ukm.my/
language	English
description	Cobalt oxide (CoO) has been widely studied for photocatalyst of water splitting and displaying a high-efficiency material. This paper reports a Density Functional Theory (DFT) study on the electronic properties of rock-salt CoO and analyzes effects of cations (Ni and Fe) and anions (N and F) dopants on the electronic properties. For this purpose, CASTEP software used for first principles plane-wave pseudo-potential calculations at different functional, i.e: GGA-PW91 and LDA. The electronic calculations of the CoO optimized structure showed a metallic structure if without considering spin-orbital interactions. After considering the spin-orbital interaction calculation, the CoO band structure possessed indirect and direct band gaps. The direct bandgap by GGA-PW91 calculation is 2.10 eV, it was agreed to the experimentally reported value of approximately 1.9-2.6 eV. Meanwhile, Ni, Fe, and F-doped CoO, demonstrating decreased CoO direct band gaps to 1.70 eV, 1.80 eV, and 1.73 eV, respectively. While N-doped CoO increased the CoO direct bandgap to 3.05 eV. All dopants shifted the conduction and valence bands position, where Ni-doped CoO band edges keep straddle to the redox potential of water splitting. Among other elements in this study, Ni is a more desirable dopant of CoO to enhance photoelectrochemical hydrogen production.
format	Article
author	Siti Nurul Falaein Moridon, Khuzaimah Arifin, Amilia Linggawati, Lorna Jeffery Minggu, Mohammad Kassim,
spellingShingle	Siti Nurul Falaein Moridon, Khuzaimah Arifin, Amilia Linggawati, Lorna Jeffery Minggu, Mohammad Kassim, Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
author_facet	Siti Nurul Falaein Moridon, Khuzaimah Arifin, Amilia Linggawati, Lorna Jeffery Minggu, Mohammad Kassim,
author_sort	Siti Nurul Falaein Moridon,
title	Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
title_short	Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
title_full	Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
title_fullStr	Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
title_full_unstemmed	Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)
title_sort	density functional theory study on the electronic properties of doped-cobalt oxide (coo)
publisher	Penerbit Universiti Kebangsaan Malaysia
publishDate	2020
url	http://journalarticle.ukm.my/14843/1/08.pdf http://journalarticle.ukm.my/14843/ http://www.ukm.my/jkukm/volume-321-2020/
_version_	1672611744430686208

Density functional theory study on the electronic properties of doped-cobalt oxide (CoO)

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