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Mott Quantum Critical Points at Finite Doping

Maria Chatzieleftheriou, Alexander Kowalski, Maja Berović, A. Amaricci, Massimo Capone, Lorenzo De Leo, Giorgio Sangiovanni, Luca de’ Medici

2023Physical Review Letters20 citationsDOI

Abstract

We demonstrate that a finite-doping quantum critical point (QCP) naturally descends from the existence of a first-order Mott transition in the phase diagram of a strongly correlated material. In a prototypical case of a first-order Mott transition the surface associated with the equation of state for the homogeneous system is "folded" so that in a range of parameters stable metallic and insulating phases exist and are connected by an unstable metallic branch. Here we show that tuning the chemical potential, the zero-temperature equation of state gradually unfolds. Under general conditions, we find that the Mott transition evolves into a first-order transition between two metals, associated with a phase separation region ending in the finite-doping QCP. This scenario is here demonstrated solving a minimal multiorbital Hubbard model relevant for the iron-based superconductors, but its origin-the splitting of the atomic ground state multiplet by a small energy scale, here Hund's coupling-is much more general. A strong analogy with cuprate superconductors is traced.

Topics & Concepts

Quantum critical pointSuperconductivityCondensed matter physicsPhysicsMott transitionPhase diagramCuprateQuantum phase transitionHubbard modelGround stateStrongly correlated materialDopingQuantum mechanicsPhase transitionPhase (matter)ElectronPhysics of Superconductivity and MagnetismIron-based superconductors researchAdvanced Condensed Matter Physics
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