Unified picture of the doping dependence of superconducting transition temperatures in alkali metal/ammonia intercalated FeSe

Daniel Guterding; Harald O. Jeschke; P. J. Hirschfeld; Roser Valentí

doi:10.1103/PhysRevB.91.041112

Unified picture of the doping dependence of superconducting transition temperatures in alkali metal/ammonia intercalated FeSe

Daniel Guterding, Harald O. Jeschke, P. J. Hirschfeld, Roser Valentí

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

52 Citations (Scopus)

Abstract

In the recently synthesized Lix(NH2)y(NH3)zFe2Se2 family of iron chalcogenides, a molecular spacer consisting of lithium ions, lithium amide, and ammonia separates the layers of FeSe. It has been shown that upon variation of the chemical composition of the spacer layer, superconducting transition temperatures can reach Tc∼44K, but the relative importance of the layer separation and effective doping to the Tc enhancement is currently unclear. Using state of the art band structure unfolding techniques, we construct eight-orbital models from ab initio density functional theory calculations for these materials. Within an RPA spin-fluctuation approach, we show that the electron doping enhances the superconducting pairing, which is of s± symmetry and explain the experimentally observed limit to Tc in the molecular spacer intercalated FeSe class of materials.

Original language	English
Article number	041112
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	91
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevB.91.041112
Publication status	Published - Jan 15 2015
Externally published	Yes

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.91.041112

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abstract = "In the recently synthesized Lix(NH2)y(NH3)zFe2Se2 family of iron chalcogenides, a molecular spacer consisting of lithium ions, lithium amide, and ammonia separates the layers of FeSe. It has been shown that upon variation of the chemical composition of the spacer layer, superconducting transition temperatures can reach Tc∼44K, but the relative importance of the layer separation and effective doping to the Tc enhancement is currently unclear. Using state of the art band structure unfolding techniques, we construct eight-orbital models from ab initio density functional theory calculations for these materials. Within an RPA spin-fluctuation approach, we show that the electron doping enhances the superconducting pairing, which is of s± symmetry and explain the experimentally observed limit to Tc in the molecular spacer intercalated FeSe class of materials.",

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AU - Guterding, Daniel

AU - Jeschke, Harald O.

AU - Hirschfeld, P. J.

AU - Valentí, Roser

PY - 2015/1/15

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AB - In the recently synthesized Lix(NH2)y(NH3)zFe2Se2 family of iron chalcogenides, a molecular spacer consisting of lithium ions, lithium amide, and ammonia separates the layers of FeSe. It has been shown that upon variation of the chemical composition of the spacer layer, superconducting transition temperatures can reach Tc∼44K, but the relative importance of the layer separation and effective doping to the Tc enhancement is currently unclear. Using state of the art band structure unfolding techniques, we construct eight-orbital models from ab initio density functional theory calculations for these materials. Within an RPA spin-fluctuation approach, we show that the electron doping enhances the superconducting pairing, which is of s± symmetry and explain the experimentally observed limit to Tc in the molecular spacer intercalated FeSe class of materials.

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Unified picture of the doping dependence of superconducting transition temperatures in alkali metal/ammonia intercalated FeSe

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