First-Principles Investigation of Energetics and Electronic Structures of Ni and Sc Co-Doped MgH sub( 2)

First-principles calculations were used to study the energetics and electronic structures of Ni and Sc co-doped MgH sub( 2) system. The preferential positions for dopants were determined by the minimal total electronic energy. The results of formation enthalpy indicate that Ni and Sc co-doped MgH su...

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Veröffentlicht in:	American journal of analytical chemistry 2016-01, Vol.7 (1), p.34-34
Hauptverfasser:	Sun, Gaili, Li, Yuanyuan, Zhao, Xinxin, Mi, Yiming, Wang, Lili
Format:	Artikel
Sprache:	eng
Schlagworte:	Dehydrogenation Desorption Dopants Electronic structure Enthalpy Hydrogen storage Magnesium Nickel
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creator	Sun, Gaili Li, Yuanyuan Zhao, Xinxin Mi, Yiming Wang, Lili
description	First-principles calculations were used to study the energetics and electronic structures of Ni and Sc co-doped MgH sub( 2) system. The preferential positions for dopants were determined by the minimal total electronic energy. The results of formation enthalpy indicate that Ni and Sc co-doped MgH sub( 2) system is more stable than Ni single-doped system. The hydrogen desorption enthalpies of these two hydrides are investigated. Ni and Sc co-doping can improve the dehydrogenation properties of MgH sub( 2). The lowest hydrogen desorption enthalpy of 0.30 eV appears in co-doped system, which is significantly lower than that of Ni doping. The electronic structure analysis illustrates that the hybridization of dopants with Mg and H atom together weakens the Mg-H interaction. And the Mg-H bonds are more susceptible to dissociate by Ni and Sc co-doping because of the reduced magnitude of Mg-H hybridization peaks. These behaviors effectively improve the dehydrogenation properties of Ni and Sc co-doped cases.
doi_str_mv	10.4236/ajac.2016.71004
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The preferential positions for dopants were determined by the minimal total electronic energy. The results of formation enthalpy indicate that Ni and Sc co-doped MgH sub( 2) system is more stable than Ni single-doped system. The hydrogen desorption enthalpies of these two hydrides are investigated. Ni and Sc co-doping can improve the dehydrogenation properties of MgH sub( 2). The lowest hydrogen desorption enthalpy of 0.30 eV appears in co-doped system, which is significantly lower than that of Ni doping. The electronic structure analysis illustrates that the hybridization of dopants with Mg and H atom together weakens the Mg-H interaction. And the Mg-H bonds are more susceptible to dissociate by Ni and Sc co-doping because of the reduced magnitude of Mg-H hybridization peaks. 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subjects	Dehydrogenation Desorption Dopants Electronic structure Enthalpy Hydrogen storage Magnesium Nickel
title	First-Principles Investigation of Energetics and Electronic Structures of Ni and Sc Co-Doped MgH sub( 2)
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