Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets

Yifeng Han; Meixia Wu; Churen Gui; Chuanhui Zhu; Zhongxiong Sun; Mei Huan Zhao; Aleksandra A. Savina; Artem M. Abakumov; Biao Wang; Feng Huang; Lun Hua He; Jie Chen; Qingzhen Huang; Mark Croft; Steven Ehrlich; Syed Khalid; Zheng Deng; Changqing Jin; Christoph P. Grams; Joachim Hemberger; Xueyun Wang; Jiawang Hong; Umut Adem; Meng Ye; Shuai Dong; Man Rong Li

doi:10.1038/s41535-020-00294-2

Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets

Yifeng Han
, Meixia Wu
, Churen Gui
, Chuanhui Zhu
, Zhongxiong Sun
, Mei Huan Zhao
, Aleksandra A. Savina
, Artem M. Abakumov
, Biao Wang
, Feng Huang
, Lun Hua He
, Jie Chen
, Qingzhen Huang
, Mark Croft
, Steven Ehrlich
, Syed Khalid
, Zheng Deng
, Changqing Jin
, Christoph P. Grams
, Joachim Hemberger

Xueyun Wang, Jiawang Hong, Umut Adem, Meng Ye, Shuai Dong, Man Rong Li^*

^*Corresponding author for this work

School of Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

21 Citations (Scopus)

Abstract

Rational design of technologically important exotic perovskites is hampered by the insufficient geometrical descriptors and costly and extremely high-pressure synthesis, while the big-data driven compositional identification and precise prediction entangles full understanding of the possible polymorphs and complicated multidimensional calculations of the chemical and thermodynamic parameter space. Here we present a rapid systematic data-mining-driven approach to design exotic perovskites in a high-throughput and discovery speed of the A₂BB’O₆ family as exemplified in A₃TeO₆. The magnetoelectric polar magnet Co₃TeO₆, which is theoretically recognized and experimentally realized at 5 GPa from the six possible polymorphs, undergoes two magnetic transitions at 24 and 58 K and exhibits helical spin structure accompanied by magnetoelastic and magnetoelectric coupling. We expect the applied approach will accelerate the systematic and rapid discovery of new exotic perovskites in a high-throughput manner and can be extended to arbitrary applications in other families.

Original language	English
Article number	92
Journal	npj Quantum Materials
Volume	5
Issue number	1
DOIs	https://doi.org/10.1038/s41535-020-00294-2
Publication status	Published - Dec 2020

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Han, Y., Wu, M., Gui, C., Zhu, C., Sun, Z., Zhao, M. H., Savina, A. A., Abakumov, A. M., Wang, B., Huang, F., He, L. H., Chen, J., Huang, Q., Croft, M., Ehrlich, S., Khalid, S., Deng, Z., Jin, C., Grams, C. P., ... Li, M. R. (2020). Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets. npj Quantum Materials, 5(1), Article 92. https://doi.org/10.1038/s41535-020-00294-2

@article{d4b450dc2b5f46faabe9fb979275c382,

title = "Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets",

abstract = "Rational design of technologically important exotic perovskites is hampered by the insufficient geometrical descriptors and costly and extremely high-pressure synthesis, while the big-data driven compositional identification and precise prediction entangles full understanding of the possible polymorphs and complicated multidimensional calculations of the chemical and thermodynamic parameter space. Here we present a rapid systematic data-mining-driven approach to design exotic perovskites in a high-throughput and discovery speed of the A2BB{\textquoteright}O6 family as exemplified in A3TeO6. The magnetoelectric polar magnet Co3TeO6, which is theoretically recognized and experimentally realized at 5 GPa from the six possible polymorphs, undergoes two magnetic transitions at 24 and 58 K and exhibits helical spin structure accompanied by magnetoelastic and magnetoelectric coupling. We expect the applied approach will accelerate the systematic and rapid discovery of new exotic perovskites in a high-throughput manner and can be extended to arbitrary applications in other families.",

author = "Yifeng Han and Meixia Wu and Churen Gui and Chuanhui Zhu and Zhongxiong Sun and Zhao, \{Mei Huan\} and Savina, \{Aleksandra A.\} and Abakumov, \{Artem M.\} and Biao Wang and Feng Huang and He, \{Lun Hua\} and Jie Chen and Qingzhen Huang and Mark Croft and Steven Ehrlich and Syed Khalid and Zheng Deng and Changqing Jin and Grams, \{Christoph P.\} and Joachim Hemberger and Xueyun Wang and Jiawang Hong and Umut Adem and Meng Ye and Shuai Dong and Li, \{Man Rong\}",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s).",

year = "2020",

month = dec,

doi = "10.1038/s41535-020-00294-2",

language = "English",

volume = "5",

journal = "npj Quantum Materials",

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Han, Y, Wu, M, Gui, C, Zhu, C, Sun, Z, Zhao, MH, Savina, AA, Abakumov, AM, Wang, B, Huang, F, He, LH, Chen, J, Huang, Q, Croft, M, Ehrlich, S, Khalid, S, Deng, Z, Jin, C, Grams, CP, Hemberger, J, Wang, X , Hong, J, Adem, U, Ye, M, Dong, S & Li, MR 2020, 'Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets', npj Quantum Materials, vol. 5, no. 1, 92. https://doi.org/10.1038/s41535-020-00294-2

TY - JOUR

T1 - Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets

AU - Han, Yifeng

AU - Wu, Meixia

AU - Gui, Churen

AU - Zhu, Chuanhui

AU - Sun, Zhongxiong

AU - Zhao, Mei Huan

AU - Savina, Aleksandra A.

AU - Abakumov, Artem M.

AU - Wang, Biao

AU - Huang, Feng

AU - He, Lun Hua

AU - Chen, Jie

AU - Huang, Qingzhen

AU - Croft, Mark

AU - Ehrlich, Steven

AU - Khalid, Syed

AU - Deng, Zheng

AU - Jin, Changqing

AU - Grams, Christoph P.

AU - Hemberger, Joachim

AU - Wang, Xueyun

AU - Hong, Jiawang

AU - Adem, Umut

AU - Ye, Meng

AU - Dong, Shuai

AU - Li, Man Rong

PY - 2020/12

Y1 - 2020/12

N2 - Rational design of technologically important exotic perovskites is hampered by the insufficient geometrical descriptors and costly and extremely high-pressure synthesis, while the big-data driven compositional identification and precise prediction entangles full understanding of the possible polymorphs and complicated multidimensional calculations of the chemical and thermodynamic parameter space. Here we present a rapid systematic data-mining-driven approach to design exotic perovskites in a high-throughput and discovery speed of the A2BB’O6 family as exemplified in A3TeO6. The magnetoelectric polar magnet Co3TeO6, which is theoretically recognized and experimentally realized at 5 GPa from the six possible polymorphs, undergoes two magnetic transitions at 24 and 58 K and exhibits helical spin structure accompanied by magnetoelastic and magnetoelectric coupling. We expect the applied approach will accelerate the systematic and rapid discovery of new exotic perovskites in a high-throughput manner and can be extended to arbitrary applications in other families.

AB - Rational design of technologically important exotic perovskites is hampered by the insufficient geometrical descriptors and costly and extremely high-pressure synthesis, while the big-data driven compositional identification and precise prediction entangles full understanding of the possible polymorphs and complicated multidimensional calculations of the chemical and thermodynamic parameter space. Here we present a rapid systematic data-mining-driven approach to design exotic perovskites in a high-throughput and discovery speed of the A2BB’O6 family as exemplified in A3TeO6. The magnetoelectric polar magnet Co3TeO6, which is theoretically recognized and experimentally realized at 5 GPa from the six possible polymorphs, undergoes two magnetic transitions at 24 and 58 K and exhibits helical spin structure accompanied by magnetoelastic and magnetoelectric coupling. We expect the applied approach will accelerate the systematic and rapid discovery of new exotic perovskites in a high-throughput manner and can be extended to arbitrary applications in other families.

UR - https://www.scopus.com/pages/publications/85097312550

U2 - 10.1038/s41535-020-00294-2

DO - 10.1038/s41535-020-00294-2

M3 - Article

AN - SCOPUS:85097312550

SN - 2397-4648

VL - 5

JO - npj Quantum Materials

JF - npj Quantum Materials

IS - 1

M1 - 92

ER -

Data-driven computational prediction and experimental realization of exotic perovskite-related polar magnets

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