Ferro-orbital ordering transition in Iron telluride fe1+yte

David Fobes; Igor A. Zaliznyak; Zhijun Xu; Ruidan Zhong; Genda Gu; John M. Tranquada; Leland Harriger; Deepak Singh; V. Ovidiu Garlea; Mark Lumsden; Barry Winn

doi:10.1103/PhysRevLett.112.187202

Ferro-orbital ordering transition in Iron telluride fe1+yte

David Fobes, Igor A. Zaliznyak, Zhijun Xu, Ruidan Zhong, Genda Gu, John M. Tranquada, Leland Harriger, Deepak Singh, V. Ovidiu Garlea, Mark Lumsden, Barry Winn

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41 Scopus citations

Abstract

Fe1+yTe with 0.05 exhibits a first-order phase transition on cooling to a state with a lowered structural symmetry, bicollinear antiferromagnetic order, and metallic conductivity, dρ/dT>0. Here, we study samples with y=0.09(1), where the frustration effects of the interstitial Fe decouple different orders, leading to a sequence of transitions. While the lattice distortion is closely followed by incommensurate magnetic order, the development of bicollinear order and metallic electronic coherence is uniquely associated with a separate hysteretic first-order transition, at a markedly lower temperature, to a phase with dramatically enhanced bond-order wave (BOW) order. The BOW state suggests ferro-orbital ordering, where electronic delocalization in ferromagnetic zigzag chains decreases local spin and results in metallic transport.

Original language	English
Article number	187202
Journal	Physical Review Letters
Volume	112
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.112.187202
State	Published - May 9 2014

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10.1103/PhysRevLett.112.187202

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abstract = "Fe1+yTe with 0.05 exhibits a first-order phase transition on cooling to a state with a lowered structural symmetry, bicollinear antiferromagnetic order, and metallic conductivity, dρ/dT>0. Here, we study samples with y=0.09(1), where the frustration effects of the interstitial Fe decouple different orders, leading to a sequence of transitions. While the lattice distortion is closely followed by incommensurate magnetic order, the development of bicollinear order and metallic electronic coherence is uniquely associated with a separate hysteretic first-order transition, at a markedly lower temperature, to a phase with dramatically enhanced bond-order wave (BOW) order. The BOW state suggests ferro-orbital ordering, where electronic delocalization in ferromagnetic zigzag chains decreases local spin and results in metallic transport.",

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AU - Fobes, David

AU - Zaliznyak, Igor A.

AU - Xu, Zhijun

AU - Zhong, Ruidan

AU - Gu, Genda

AU - Tranquada, John M.

AU - Harriger, Leland

AU - Singh, Deepak

AU - Garlea, V. Ovidiu

AU - Lumsden, Mark

AU - Winn, Barry

PY - 2014/5/9

Y1 - 2014/5/9

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AB - Fe1+yTe with 0.05 exhibits a first-order phase transition on cooling to a state with a lowered structural symmetry, bicollinear antiferromagnetic order, and metallic conductivity, dρ/dT>0. Here, we study samples with y=0.09(1), where the frustration effects of the interstitial Fe decouple different orders, leading to a sequence of transitions. While the lattice distortion is closely followed by incommensurate magnetic order, the development of bicollinear order and metallic electronic coherence is uniquely associated with a separate hysteretic first-order transition, at a markedly lower temperature, to a phase with dramatically enhanced bond-order wave (BOW) order. The BOW state suggests ferro-orbital ordering, where electronic delocalization in ferromagnetic zigzag chains decreases local spin and results in metallic transport.

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Ferro-orbital ordering transition in Iron telluride fe1+yte

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