Spatial inhomogeneity and the metal-insulator transition in 
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Lechermann, Frank; Han, Qiang; Millis, Andrew J.

doi:10.1103/physrevresearch.2.033490

Phys. Rev. Research

2020

DOI: 10.1103/physrevresearch.2.033490

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Spatial inhomogeneity and the metal-insulator transition in Ca3(Ru1−xTix)2

Frank Lechermann

Qiang Han

Andrew J. Millis

Abstract: Turning a pristine Mott insulator into a correlated metal by chemical doping is a common procedure in strongly correlated materials physics, e.g., underlying the phenomenology of high-T c cuprates. The ruthenate bilayer compound Ca 3 Ru 2 O 7 is a prominent example of a reversed case, namely, a correlated metal at stoichiometry that realizes a transition into an insulating state via Ti doping. We here investigate this puzzling metal-insulator transition (MIT) by first-principles many-body theory and elucidate … Show more

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Cited by 5 publications

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From basic properties to the Mott design of correlated delafossites

Lechermann

2021

npj Comput Mater

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The natural-heterostructure concept realized in delafossites highlights these layered oxides. While metallic, band- or Mott-insulating character may be associated with individual layers, inter-layer coupling still plays a decisive role. We review the correlated electronic structure of PdCoO2, PdCrO2, and AgCrO2, showing that layer-entangled electronic states can deviate from standard classifications of interacting systems. This finding opens up possibilities for materials design in a subtle Mott-critical regime. Manipulated Hidden-Mott physics, correlation-induced semimetallicity, or Dirac/flat-band dispersions in a Mott background are emerging features. Together with achievements in the experimental preparation, this inaugurates an exciting research field in the arena of correlated materials.

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From basic properties to the Mott design of correlated delafossites

Lechermann

2021

npj Comput Mater

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Lattice distortions and the metal–insulator transition in pure and Ti-substituted Ca₃Ru₂O₇

Petkov¹,

Rao²,

Zafar³

et al. 2022

J. Phys.: Condens. Matter

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We report pair distribution function studies on the relationship between the metal-insulator transition (MIT) and lattice distortions in pure and Ti-substituted bilayer Ca3Ru2O7. Structural refinements performed as a function of temperature, magnetic field and length scale reveal the presence of lattice distortions not only within but also orthogonal to the bilayers. Because of the distortions, the local and average crystal structure differ across a broad temperature region extending from room temperature to temperatures below the MIT. It The coexistence of distinct lattice distortions is likely to be behind the marked structural flexibility of Ca3Ru2O7 under external stimuli. This observation highlights the ubiquity of lattice distortions in an archetypal Mott system and calls for similar studies on other families of strongly correlated materials.

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Elastic-stripe formation at electronic transitions

Chiriacò

Millis²

2023

Phys. Rev. B

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Spatial inhomogeneity and the metal-insulator transition in Ca3(Ru1−xTix)2

Cited by 5 publications

References 37 publications

From basic properties to the Mott design of correlated delafossites

From basic properties to the Mott design of correlated delafossites

Lattice distortions and the metal–insulator transition in pure and Ti-substituted Ca₃Ru₂O₇

Elastic-stripe formation at electronic transitions

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Spatial inhomogeneity and the metal-insulator transition in Ca3(Ru1−xTix)2

Cited by 5 publications

References 37 publications

From basic properties to the Mott design of correlated delafossites

From basic properties to the Mott design of correlated delafossites

Lattice distortions and the metal–insulator transition in pure and Ti-substituted Ca3Ru2O7

Elastic-stripe formation at electronic transitions

Contact Info

Product

Resources

About

Lattice distortions and the metal–insulator transition in pure and Ti-substituted Ca₃Ru₂O₇