ECFL theory accounts for density-dependent quasilinear resistivity, small quasiparticle weight, and emergent low-T scales in single-layer high-Tc systems via the t-J model.
Extremely correlated fermi liquid of $t$-$J$ model in two dimensions
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abstract
We study the two-dimensional $t$-$J$ model with second neighbor hopping parameter $t'$ and in a broad range of doping $\delta$ using a closed set of equations from the {\em Extremely Correlated Fermi Liquid} (ECFL) theory. We obtain asymmetric energy distribution curves and symmetric momentum distribution curves of the spectral function, consistent with experimental data. We further explore the Fermi surface and local density of states for different parameter sets. Using the spectral function, we calculate the resistivity, Hall number and spin susceptibility. The curvature change in the resistivity curves with varying $\delta$ is presented and connected to intensity loss in Angle Resolved Photoemission Spectroscopy (ARPES) experiments. We also discuss the role of the super-exchange $J$ in the spectral function and the resistivity in the optimal to overdoped density regimes.
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cond-mat.str-el 1years
2026 1verdicts
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Overview of the Theory of Extremely Correlated Fermi Liquids
ECFL theory accounts for density-dependent quasilinear resistivity, small quasiparticle weight, and emergent low-T scales in single-layer high-Tc systems via the t-J model.