Polar metallic behavior of strained antiperovskites ACNi3 (A=Mg,Zn, and Cd) from first principles

Yasuhide Mochizuki; Yu Kumagai; Hirofumi Akamatsu; Fumiyasu Oba

doi:10.1103/PhysRevMaterials.2.125004

Polar metallic behavior of strained antiperovskites ACNi3 (A=Mg,Zn, and Cd) from first principles

Yasuhide Mochizuki, Yu Kumagai, Hirofumi Akamatsu, Fumiyasu Oba

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20 Citations (Scopus)

Abstract

Stable structures of metallic antiperovskites ACNi3(A=Mg,Zn, and Cd) under epitaxial strain are explored using first-principles lattice dynamics calculations. Although the ground states of ACNi3 are cubic nonpolar phases without structural distortion, transitions to polar phases are predicted to arise in these compounds under compressive strain while maintaining metallic states. In particular, the polar phase of MgCNi3 would be attainable with moderate strain of a few percent. The polar distortions are considered to be generated by the enhancement of the hybridization between C 2p and Ni 3d states, which is a mechanism analogous to that of the previously discovered polar metal CeSiPt3.

Original language	English
Article number	125004
Journal	Physical Review Materials
Volume	2
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevMaterials.2.125004
Publication status	Published - Dec 26 2018

All Science Journal Classification (ASJC) codes

General Materials Science
Physics and Astronomy (miscellaneous)

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10.1103/PhysRevMaterials.2.125004

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abstract = "Stable structures of metallic antiperovskites ACNi3(A=Mg,Zn, and Cd) under epitaxial strain are explored using first-principles lattice dynamics calculations. Although the ground states of ACNi3 are cubic nonpolar phases without structural distortion, transitions to polar phases are predicted to arise in these compounds under compressive strain while maintaining metallic states. In particular, the polar phase of MgCNi3 would be attainable with moderate strain of a few percent. The polar distortions are considered to be generated by the enhancement of the hybridization between C 2p and Ni 3d states, which is a mechanism analogous to that of the previously discovered polar metal CeSiPt3.",

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AU - Mochizuki, Yasuhide

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AU - Akamatsu, Hirofumi

AU - Oba, Fumiyasu

N1 - Publisher Copyright: © 2018 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

PY - 2018/12/26

Y1 - 2018/12/26

N2 - Stable structures of metallic antiperovskites ACNi3(A=Mg,Zn, and Cd) under epitaxial strain are explored using first-principles lattice dynamics calculations. Although the ground states of ACNi3 are cubic nonpolar phases without structural distortion, transitions to polar phases are predicted to arise in these compounds under compressive strain while maintaining metallic states. In particular, the polar phase of MgCNi3 would be attainable with moderate strain of a few percent. The polar distortions are considered to be generated by the enhancement of the hybridization between C 2p and Ni 3d states, which is a mechanism analogous to that of the previously discovered polar metal CeSiPt3.

AB - Stable structures of metallic antiperovskites ACNi3(A=Mg,Zn, and Cd) under epitaxial strain are explored using first-principles lattice dynamics calculations. Although the ground states of ACNi3 are cubic nonpolar phases without structural distortion, transitions to polar phases are predicted to arise in these compounds under compressive strain while maintaining metallic states. In particular, the polar phase of MgCNi3 would be attainable with moderate strain of a few percent. The polar distortions are considered to be generated by the enhancement of the hybridization between C 2p and Ni 3d states, which is a mechanism analogous to that of the previously discovered polar metal CeSiPt3.

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Polar metallic behavior of strained antiperovskites ACNi3 (A=Mg,Zn, and Cd) from first principles

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