The Iso-electronic Series Ca2-xSrxRuO4: Structural Distortion, Effective Dimensionality, Spin Fluctuations and Quantum Criticality

Abstract

The iso-electronic d4 compounds of the 4d series show rich phase diagrams due to competing spin, charge and orbital degrees of freedom in presence of strong correlations and structural distortions. One such iso-electronic series, Ca2-xSrxRuO4, is studied within the GGA (and spin-orbit coupled GGA) plus DMFT formalism using the hybridization expansion of continuous time Quantum Monte Carlo solver. While the local dynamical correlations make Sr2RuO4 a Hund's metal, they drive Ca2RuO4 to a Mott insulating ground state. We study the dynamic and static single-particle and local irreducible vertex-corrected two-particle responses at three different points (x = 2.0, 0.5, 0.0) to understand the anomalous cross-over from Hund's metal (x = 2.0 ) to a Mott insulator (x = 0 ) and find that a structural distortion is likely to be responsible for the cross-over. Further, dynamical correlations reveal that the band-width (W) of the Hund's metal is larger than its effective local Hubbard U, and a finite Hund's coupling JH helps it remain in a bad metallic and nearly spin-frozen state over a large temperature range. Ca2RuO4, on the other hand, is intrinsically driven to the proximity of a Mott transition due to narrowing of band width (U/W > 1.5), though its finite temperature excitations indicate bad metallicity. We show that there is a critical end point of second-order structural transition at x = 0.5, where spin fluctuations become critically singular and follow the exact scaling of conformally invariant boundary field theory. The critical end point of quasi-3D nature is associated with an effective dimensional cross-over between the x = 2.0 and x=0.0 quasi-2D structures. Finally we draw a modified magnetic phase diagram of the material, showing a fan-like region starting from the quantum critical end point at x = 0.5.