High-pressure investigations on the semi-Heusler compound CuMnSb

Malavi, Pallavi; Song, Jing; Bi, Wenli; Regnat, Alexander; Zhu, Linghan; Bauer, Andreas; Senyshyn, Anatoliy; Yang, Li; Pfleiderer, C.; Schilling, J. S.

doi:10.1103/physrevb.98.054431

Cited by 5 publications

(2 citation statements)

References 45 publications

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“…The experimental confirmation of topological nature of materials studied can be done through several experiments like angle resolved photo-emission spectroscopy measurements [50], magneto-transport [51] and quantum oscillations in resistance of material as a function of magnetic field (the Shubnikov-de Hass effect) and NMR study [52][53][54][55]. Also, there are several experimental reports which are relevant to pressure dependent synthesis of the half-Heusler materials via various techniques like diamond anvil cell [56][57][58]. We expect that the findings reported here will further encourage the quest for topological insulating behaviour in half-Heusler compounds.…”

Section: Discussionmentioning

confidence: 99%

First principle based investigation of topological insulating phase in half-Heusler family NaYO (Y = Ag, Au, and Cu)

Kore¹,

Ara²,

Singh³

2022

J. Phys.: Condens. Matter

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The ternary half-Heusler compounds have shown great potential for realizing new 3D topological insulators. With band gap tuning and spin orbit coupling these compounds may undergo topological phase transitions. In present work, we explore the possibility of realizing a topological insulating phase in half-Heusler family NaYO (Y = Ag, Au, and Cu). We find that for NaAgO, external strain ($\sim$19 \%) along with spin-orbit coupling, is required to achieve band-inversion at $\Gamma$ high-symmetry point and leads to phase transition from trivial to non-trivial topological insulating phase. In case of NaAuO and NaCuO, non-trivial phase appears in their equilibrium lattice constant, hence only spin-orbit coupling is enough to achieve band-inversion leading to non-trivial topology. The non-centrosymmetric nature of crystal geometry leads to the formation of two twofold degenerate point nodes near the Fermi level.

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Section: Discussionmentioning

confidence: 99%

First principle based investigation of topological insulating phase in half-Heusler family NaYO (Y = Ag, Au, and Cu)

Kore¹,

Ara²,

Singh³

2022

J. Phys.: Condens. Matter

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“…The electronic properties of NiXSn(X = Zr, Hf) alloys [28] have been investigated using ab initio calculations and conversion from the indirect to direct band gap at 50 GPa and 127 GPa for NiZrSn and NiHfSn alloys, respectively. CuMnSb semi-Heusler alloys [29] were measured under pressure, and it was found that the Neel temperature of CuMnSb increased with pressure. The semimetallic cubic phase becomes the semimetallic tetragonal phase at about 8 GPa.…”

mentioning

confidence: 99%

Half‐metallicity, magnetism, mechanical, thermal, and phonon properties of FeCrTe and FeCrSe half‐Heusler alloys under pressure

Paudel

Kaphle

Batouche

et al. 2020

Int J of Quantum Chemistry

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The half-metallicity of Heusler alloys is quite sensitive to high pressure and disorder. To understand this phenomenon better, we systematically studied the half-metallic nature, magnetism, phonon, and thermomechanical properties of FeCrTe and FeCrSe Heusler alloys under high pressure using ab initio calculations based on density functional theory. The ground-state lattice constants for FeCrTe and FeCrSe alloys are 5.93 and 5.57 Å, respectively, consistent with available theoretical results. Formation energy, cohesive energy, elastic constants, and phonon dispersion confirmed that both compounds are thermodynamically and mechanically stable. The FeCrTe and FeCrSe alloys showed a half-metallic character with a band gap of 0.68 and 0.58 eV at 0 GPa pressure, respectively, and magnetic moments of 2.01 μ B for both alloys, using generalized gradient approximation (GGA) approximation. FeCrTe alloy changes from metallic to half-metallic above 30 GPa pressure using GGA + U. The elastic properties were scrutinized, and it was found that, at 0 GPa pressure, FeCrTe is ductile, and FeCrSe is brittle. Under pressure, FeCrSe becomes brittle above 10 GPa pressure. Average sound velocity V m , Debye temperature Ɵ D , and heat capacity C V were predicted under pressure. These outcomes will improve the integration of Fe-based half-Heusler alloys in spintronic devices.

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Enhanced Curie temperature and spin polarization in Co-based compounds under pressure: A first principles investigation

Rambabu

Anuroopa

Raja

et al. 2020

Solid State Sciences

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High-pressure investigations on the semi-Heusler compound CuMnSb

Cited by 5 publications

References 45 publications

First principle based investigation of topological insulating phase in half-Heusler family NaYO (Y = Ag, Au, and Cu)

First principle based investigation of topological insulating phase in half-Heusler family NaYO (Y = Ag, Au, and Cu)

Half‐metallicity, magnetism, mechanical, thermal, and phonon properties of FeCrTe and FeCrSe half‐Heusler alloys under pressure

Enhanced Curie temperature and spin polarization in Co-based compounds under pressure: A first principles investigation

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