First-Order Melting of a Weak Spin-Orbit Mott Insulator into a Correlated Metal

Tom Hogan; Z. Yamani; D. Walkup; Xiang Chen; Rebecca Dally; Thomas Z. Ward; M. P.M. Dean; John Hill; Z. Islam; Vidya Madhavan; Stephen D. Wilson

doi:10.1103/PhysRevLett.114.257203

First-Order Melting of a Weak Spin-Orbit Mott Insulator into a Correlated Metal

Tom Hogan
, Z. Yamani
, D. Walkup
, Xiang Chen
, Rebecca Dally
, Thomas Z. Ward
, M. P.M. Dean
, John Hill
, Z. Islam
, Vidya Madhavan
, Stephen D. Wilson

Quantum Heterostructures

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

44 Scopus citations

Abstract

The electronic phase diagram of the weak spin-orbit Mott insulator (Sr1-xLax)3Ir2O7 is determined via an exhaustive experimental study. Upon doping electrons via La substitution, an immediate collapse in resistivity occurs along with a narrow regime of nanoscale phase separation comprised of antiferromagnetic, insulating regions and paramagnetic, metallic puddles persisting until x≈0.04. Continued electron doping results in an abrupt, first-order phase boundary where the Néel state is suppressed and a homogenous, correlated, metallic state appears with an enhanced spin susceptibility and local moments. As the metallic state is stabilized, a weak structural distortion develops and suggests a competing instability with the parent spin-orbit Mott state.

Original language	English
Article number	257203
Journal	Physical Review Letters
Volume	114
Issue number	25
DOIs	https://doi.org/10.1103/PhysRevLett.114.257203
State	Published - Jun 25 2015

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10.1103/PhysRevLett.114.257203

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title = "First-Order Melting of a Weak Spin-Orbit Mott Insulator into a Correlated Metal",

abstract = "The electronic phase diagram of the weak spin-orbit Mott insulator (Sr1-xLax)3Ir2O7 is determined via an exhaustive experimental study. Upon doping electrons via La substitution, an immediate collapse in resistivity occurs along with a narrow regime of nanoscale phase separation comprised of antiferromagnetic, insulating regions and paramagnetic, metallic puddles persisting until x≈0.04. Continued electron doping results in an abrupt, first-order phase boundary where the N{\'e}el state is suppressed and a homogenous, correlated, metallic state appears with an enhanced spin susceptibility and local moments. As the metallic state is stabilized, a weak structural distortion develops and suggests a competing instability with the parent spin-orbit Mott state.",

author = "Tom Hogan and Z. Yamani and D. Walkup and Xiang Chen and Rebecca Dally and Ward, \{Thomas Z.\} and Dean, \{M. P.M.\} and John Hill and Z. Islam and Vidya Madhavan and Wilson, \{Stephen D.\}",

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AU - Hogan, Tom

AU - Yamani, Z.

AU - Walkup, D.

AU - Chen, Xiang

AU - Dally, Rebecca

AU - Ward, Thomas Z.

AU - Dean, M. P.M.

AU - Hill, John

AU - Islam, Z.

AU - Madhavan, Vidya

AU - Wilson, Stephen D.

PY - 2015/6/25

Y1 - 2015/6/25

N2 - The electronic phase diagram of the weak spin-orbit Mott insulator (Sr1-xLax)3Ir2O7 is determined via an exhaustive experimental study. Upon doping electrons via La substitution, an immediate collapse in resistivity occurs along with a narrow regime of nanoscale phase separation comprised of antiferromagnetic, insulating regions and paramagnetic, metallic puddles persisting until x≈0.04. Continued electron doping results in an abrupt, first-order phase boundary where the Néel state is suppressed and a homogenous, correlated, metallic state appears with an enhanced spin susceptibility and local moments. As the metallic state is stabilized, a weak structural distortion develops and suggests a competing instability with the parent spin-orbit Mott state.

AB - The electronic phase diagram of the weak spin-orbit Mott insulator (Sr1-xLax)3Ir2O7 is determined via an exhaustive experimental study. Upon doping electrons via La substitution, an immediate collapse in resistivity occurs along with a narrow regime of nanoscale phase separation comprised of antiferromagnetic, insulating regions and paramagnetic, metallic puddles persisting until x≈0.04. Continued electron doping results in an abrupt, first-order phase boundary where the Néel state is suppressed and a homogenous, correlated, metallic state appears with an enhanced spin susceptibility and local moments. As the metallic state is stabilized, a weak structural distortion develops and suggests a competing instability with the parent spin-orbit Mott state.

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DO - 10.1103/PhysRevLett.114.257203

M3 - Article

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ER -

First-Order Melting of a Weak Spin-Orbit Mott Insulator into a Correlated Metal

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