Ab Initio Calculations of New Full Heusler Alloys Rh2ZrX (X = Al, Ga, In, Si, Ge, Sn)

Abadi, Ahmad Asadi Mohammad; Forozani, Ghasem; Baizaee, Seyyed Mahdy; Gharaati, Abdolrasoul

doi:10.1007/s10948-018-4971-6

Cited by 7 publications

(2 citation statements)

References 36 publications

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“…Spin-polarized electronic band structures along the high symmetry directions of Ru 2 TGa (T = Cr, Mn, and Co) Heusler alloys for spin-up (majorityspin) and spin-down (minority-spin) states are illustrated in Fig. 3a, b 49 The lowest valence bands in the energy region that are lower than À 6 eV in both the majority and minority spin states mainly come from the electrons of 4s orbitals of the Ga atom and the electrons of 5p orbitals of the Ru atoms for all alloys. The low-energy part around À 6 eV and 0 eV in both spin states predominantly comes from the electrons of 4d orbitals of the Ru atom and the electrons of the 3d orbitals of the T (Cr, Mn, and Co) atom.…”

Section: Magnetic and Electronic Propertiesmentioning

confidence: 99%

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

Candan

2019

Journal of Elec Materi

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A theoretical study of magnetic, electronic, mechanic, anisotropic elastic, and vibrational properties of Ru 2 TGa (T = Cr, Mn, and Co) Heusler alloys has been extensively investigated by the first-principles method using the generalized gradient approximation. Structural parameters such as lattice constant (a 0), bulk modulus (B) and first pressure derivative of bulk modulus (B¢) were obtained by using the Murnaghan equation. The calculated formation enthalpies (DH f) showed that these alloys are thermodynamically stable. The total spin magnetic moments per unit cell of Ru 2 TGa (T = Cr, Mn, and Co) alloys were found to be 1.16 l B , 2.16 l B and 0.29 l B , respectively. In addition to electronic band structures along the high symmetry directions, corresponding total and partial density of states were also plotted. It was found that the spin-up states have a metallic character for all alloys, but the spin-down states of the other alloys except for Ru 2 CoGa have a pseudo-gap at the Fermi level. The bulk modulus (B), shear modulus (G), ratio of B/G, Young's modulus (E), Poisson's ratios (m), Vickers hardness (H V), sound velocities (v l , v t , and v m), Debye temperatures (H D) and melting temperatures (T melt) were obtained from elastic constants (C ij) in accordance with the Voigt-Reuss-Hill approximation. The calculated elastic constants showed that these alloys are mechanically stable and they have anisotropic character. The elastic anisotropy of the considered alloys was analyzed and pictured in great detail with 2D and 3D figures of directional dependence of Young's modulus, linear compressibility, shear modulus, and Poisson's ratio.These alloys are dynamically stable because there are no negative modes in their phonon dispersion curves.

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Section: Magnetic and Electronic Propertiesmentioning

confidence: 99%

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

Candan

2019

Journal of Elec Materi

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“…[ 10 ] For gadolinium‐based regenerators used in magnetic refrigerators, alloys were developed as a suitable alternative. [ 11 ] Most of these alloys fall into one of two types: [ 12 ] full Heusler alloys [ 13 ] with a stoichiometric composition X 2 YZ and half‐Heusler alloys [ 14 ] with chemical formula XYZ, where Z is an element of group III, IV, or V and X and Y are elements of transition metals. The alloys are known as having the regular cubic structure of Heusler alloys with space group Fm3m [ 15 ] if X has an atomic number larger than Y according to the period table Z(X) > Z(Y), or else they are known as having the inverse cubic structure of Heusler with space group F43m (N 216).…”

Section: Introductionmentioning

confidence: 99%

First‐Principles Study of the Structural, Phase‐Stability, Electronic, Magnetic, and Elastic Properties of Heusler Alloys VXRh₂ (X=Si, Ge, and Sn)

Forozani

Rasouli

2023

Physica Status Solidi (b)

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Heusler compounds have generated significant interest in spintronics due to their unique features. The structural stability, electronic structure, magnetic, and elastic properties of Heusler alloys VXRh2 (X = Sn, Ge, and Si) are investigated using first‐principles calculations of density functional theory in the Quantum Espresso code. The alloys exhibit three magnetic states (nonmagnetic, ferromagnetic, and ferrimagnetic) and several structural phases (face centered cubic (FCC) and tetragonal). It is found that pressures below 0 GPa produce the FCC phase, while greater pressures produce two tetragonal phases. VSnRh2 is a ferromagnetic metal, while VSiRh2 and VGeRh2 exhibit excellent half‐metallic ferromagnetism. The equilibrium lattice constants of VSiRh2 and VGeRh2 are stable against changes, making these Heusler alloys ideal for spintronic devices. Elastic constant computations show that compounds are mechanically stable.

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Structural stability, electronic, mechanical, and thermodynamic properties of the new MAX phases Mn2SiC1, Mn3SiC2 and Mn4SiC3: ab-initio calculations

et al. 2022

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Ab Initio Calculations of New Full Heusler Alloys Rh2ZrX (X = Al, Ga, In, Si, Ge, Sn)

Cited by 7 publications

References 36 publications

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

First‐Principles Study of the Structural, Phase‐Stability, Electronic, Magnetic, and Elastic Properties of Heusler Alloys VXRh₂ (X=Si, Ge, and Sn)

Structural stability, electronic, mechanical, and thermodynamic properties of the new MAX phases Mn2SiC1, Mn3SiC2 and Mn4SiC3: ab-initio calculations

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Ab Initio Calculations of New Full Heusler Alloys Rh2ZrX (X = Al, Ga, In, Si, Ge, Sn)

Cited by 7 publications

References 36 publications

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

Magnetic, Electronic, Mechanic, Anisotropic Elastic and Vibrational Properties of Antiferromagnetic Ru2TGa (T = Cr, Mn, and Co) Heusler Alloys

First‐Principles Study of the Structural, Phase‐Stability, Electronic, Magnetic, and Elastic Properties of Heusler Alloys VXRh2 (X=Si, Ge, and Sn)

Structural stability, electronic, mechanical, and thermodynamic properties of the new MAX phases Mn2SiC1, Mn3SiC2 and Mn4SiC3: ab-initio calculations

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First‐Principles Study of the Structural, Phase‐Stability, Electronic, Magnetic, and Elastic Properties of Heusler Alloys VXRh₂ (X=Si, Ge, and Sn)