Atomic Control of Conductivity Versus Ferromagnestism in Wide-Gap Oxides via Selective Doping: V, Nb, Ta in Anatase TiO2

Jorge Osorio-Guillén; Stephan Lany; Alex Zunger

doi:10.1103/PhysRevLett.100.036601

Atomic Control of Conductivity Versus Ferromagnestism in Wide-Gap Oxides via Selective Doping: V, Nb, Ta in Anatase TiO2

Jorge Osorio-Guillén, Stephan Lany, Alex Zunger

Materials Science

National Renewable Energy Laboratory

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

164 Scopus Citations

Abstract

We identify two general types of electronic behaviors for transition-metal impurities that introduce excess electrons in oxides. (i) The dopants introduce resonant states inside the host conduction band and produce free electrons; (ii) the dopants introduce a deep gap state that carries a magnetic moment. By combining electronic structure calculations, thermodynamic simulations, and percolation theory, we quantify these behaviors for the case of column V-B dopants in anatase TiO2. Showing behavior (i), Nb and Ta dopants can convert the insulator TiO2 into a transparent conductor. Showing behavior (ii), V dopants could convert nonmagnetic TiO2 into a ferromagnet. Whether a dopant shows behavior (i) or (ii) is encoded in its atomic d orbital energy.

Original language	American English
Article number	Article No. 036601
Number of pages	4
Journal	Physical Review Letters
Volume	100
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevLett.100.036601 https://doi.org/10.1103/PhysRevLett.100.036601
State	Published - 23 Jan 2008

NREL Publication Number

NREL/JA-590-41379

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abstract = "We identify two general types of electronic behaviors for transition-metal impurities that introduce excess electrons in oxides. (i) The dopants introduce resonant states inside the host conduction band and produce free electrons; (ii) the dopants introduce a deep gap state that carries a magnetic moment. By combining electronic structure calculations, thermodynamic simulations, and percolation theory, we quantify these behaviors for the case of column V-B dopants in anatase TiO2. Showing behavior (i), Nb and Ta dopants can convert the insulator TiO2 into a transparent conductor. Showing behavior (ii), V dopants could convert nonmagnetic TiO2 into a ferromagnet. Whether a dopant shows behavior (i) or (ii) is encoded in its atomic d orbital energy.",

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AB - We identify two general types of electronic behaviors for transition-metal impurities that introduce excess electrons in oxides. (i) The dopants introduce resonant states inside the host conduction band and produce free electrons; (ii) the dopants introduce a deep gap state that carries a magnetic moment. By combining electronic structure calculations, thermodynamic simulations, and percolation theory, we quantify these behaviors for the case of column V-B dopants in anatase TiO2. Showing behavior (i), Nb and Ta dopants can convert the insulator TiO2 into a transparent conductor. Showing behavior (ii), V dopants could convert nonmagnetic TiO2 into a ferromagnet. Whether a dopant shows behavior (i) or (ii) is encoded in its atomic d orbital energy.

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Atomic Control of Conductivity Versus Ferromagnestism in Wide-Gap Oxides via Selective Doping: V, Nb, Ta in Anatase TiO2

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