First-Principles Combinatorial Design of Transition Temperatures in Multi-Component Systems: The Case of Mn in GaAs

A. Franceschetti; S. V. Dudiy; S. V. Barabash; A. Zunger; J. Xu; M. Van Schilfgaarde

doi:10.1103/PhysRevLett.97.047202

First-Principles Combinatorial Design of Transition Temperatures in Multi-Component Systems: The Case of Mn in GaAs

A. Franceschetti
, S. V. Dudiy
, S. V. Barabash
, A. Zunger
, J. Xu
, M. Van Schilfgaarde

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

51 Scopus Citations

Abstract

The transition temperature TC of multicomponent systems-ferromagnetic, superconducting, or ferroelectric-depends strongly on the atomic arrangement, but an exhaustive search of all configurations for those that optimize TC is difficult, due to the astronomically large number of possibilities. Here we address this problem by parametrizing the TC of a set of ∼50 input configurations, calculated from first principles, in terms of configuration variables ("cluster expansion"). Once established, this expansion allows us to search almost effortlessly the transition temperature of arbitrary configurations. We apply this approach to search for the configuration of Mn dopants in GaAs having the highest ferromagnetic Curie temperature. Our general approach of cluster expanding physical properties opens the way to design based on exploring a large space of configurations.

Original language	American English
Article number	047202
Number of pages	4
Journal	Physical Review Letters
Volume	97
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevLett.97.047202 https://doi.org/10.1103/PhysRevLett.97.047202
State	Published - 2006
Externally published	Yes

NLR Publication Number

NREL/JA-590-40219

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title = "First-Principles Combinatorial Design of Transition Temperatures in Multi-Component Systems: The Case of Mn in GaAs",

abstract = "The transition temperature TC of multicomponent systems-ferromagnetic, superconducting, or ferroelectric-depends strongly on the atomic arrangement, but an exhaustive search of all configurations for those that optimize TC is difficult, due to the astronomically large number of possibilities. Here we address this problem by parametrizing the TC of a set of ∼50 input configurations, calculated from first principles, in terms of configuration variables ({"}cluster expansion{"}). Once established, this expansion allows us to search almost effortlessly the transition temperature of arbitrary configurations. We apply this approach to search for the configuration of Mn dopants in GaAs having the highest ferromagnetic Curie temperature. Our general approach of cluster expanding physical properties opens the way to design based on exploring a large space of configurations.",

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AU - Franceschetti, A.

AU - Dudiy, S. V.

AU - Barabash, S. V.

AU - Zunger, A.

AU - Xu, J.

AU - Van Schilfgaarde, M.

PY - 2006

Y1 - 2006

N2 - The transition temperature TC of multicomponent systems-ferromagnetic, superconducting, or ferroelectric-depends strongly on the atomic arrangement, but an exhaustive search of all configurations for those that optimize TC is difficult, due to the astronomically large number of possibilities. Here we address this problem by parametrizing the TC of a set of ∼50 input configurations, calculated from first principles, in terms of configuration variables ("cluster expansion"). Once established, this expansion allows us to search almost effortlessly the transition temperature of arbitrary configurations. We apply this approach to search for the configuration of Mn dopants in GaAs having the highest ferromagnetic Curie temperature. Our general approach of cluster expanding physical properties opens the way to design based on exploring a large space of configurations.

AB - The transition temperature TC of multicomponent systems-ferromagnetic, superconducting, or ferroelectric-depends strongly on the atomic arrangement, but an exhaustive search of all configurations for those that optimize TC is difficult, due to the astronomically large number of possibilities. Here we address this problem by parametrizing the TC of a set of ∼50 input configurations, calculated from first principles, in terms of configuration variables ("cluster expansion"). Once established, this expansion allows us to search almost effortlessly the transition temperature of arbitrary configurations. We apply this approach to search for the configuration of Mn dopants in GaAs having the highest ferromagnetic Curie temperature. Our general approach of cluster expanding physical properties opens the way to design based on exploring a large space of configurations.

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DO - 10.1103/PhysRevLett.97.047202

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SN - 0031-9007

VL - 97

JO - Physical Review Letters

JF - Physical Review Letters

IS - 4

M1 - 047202

ER -

First-Principles Combinatorial Design of Transition Temperatures in Multi-Component Systems: The Case of Mn in GaAs

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