用第一性原理计算尖晶石氧化物VX2O4 (X = Mn和Fe)的力学和电子性能

TURKISH PHYSICAL SOCIETY 35TH INTERNATIONAL PHYSICS CONGRESS (TPS35) Pub Date : 2019-11-25 DOI:10.1063/1.5135439

B. Yildiz, A. Erkişi, G. Surucu

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引用次数: 3

摘要

我们在广义梯度近似下进行了第一性原理密度泛函理论计算，得到了钒基尖晶石氧化物VX2O4 (X=Mn和Fe)的力学性能和电子行为，它们符合225空间数的m-3m空间群，并且由于其半金属带隙(VFe2O4的Eg=1.71 eV和VMn2O4的Eg= 0.53 eV)在标出的自旋极化电子带结构中具有良好的自旋电子应用前景。计算得到的负生成焓也表明这些材料具有热力学稳定性和结构可合成性。此外，采用应力应变法计算的弹性常数表明了上述材料的力学稳定性。我们在广义梯度近似下进行了第一性原理密度泛函理论计算，得到了钒基尖晶石氧化物VX2O4 (X=Mn和Fe)的力学性能和电子行为，它们符合225空间数的m-3m空间群，并且由于其半金属带隙(VFe2O4的Eg=1.71 eV和VMn2O4的Eg= 0.53 eV)在标出的自旋极化电子带结构中具有良好的自旋电子应用前景。计算得到的负生成焓也表明这些材料具有热力学稳定性和结构可合成性。此外，采用应力应变法计算的弹性常数表明了上述材料的力学稳定性。

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The mechanical and electronic properties of spinel oxides VX2O4 (X = Mn and Fe) by first principle calculations

We have performed first-principles density functional theory calculations within generalized-gradient approximation to obtain the mechanical properties and the electronic behavior of Vanadium based Spinel Oxides VX2O4 (X=Mn and Fe) which conform Fm-3m space group with 225 space number and are promising good candidates for spintronic applications due to their half-metallic band gaps (Eg=1.71 eV for VFe2O4 and Eg = 0.53 eV for VMn2O4) in the plotted spin-polarized electronic band structure. Also, the calculated negative formation enthalpies indicate that these materials have thermodynamic stability and structural synthesizability. Additionally, the calculated elastic constants by using stress-strain approach indicate mechanical stability of above-mentioned materials.We have performed first-principles density functional theory calculations within generalized-gradient approximation to obtain the mechanical properties and the electronic behavior of Vanadium based Spinel Oxides VX2O4 (X=Mn and Fe) which conform Fm-3m space group with 225 space number and are promising good candidates for spintronic applications due to their half-metallic band gaps (Eg=1.71 eV for VFe2O4 and Eg = 0.53 eV for VMn2O4) in the plotted spin-polarized electronic band structure. Also, the calculated negative formation enthalpies indicate that these materials have thermodynamic stability and structural synthesizability. Additionally, the calculated elastic constants by using stress-strain approach indicate mechanical stability of above-mentioned materials.

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TURKISH PHYSICAL SOCIETY 35TH INTERNATIONAL PHYSICS CONGRESS (TPS35)

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