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.
Reversal of particle-hole scattering-rate asymmetry in Anderson impurity model
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abstract
We study the particle-hole asymmetry of the scattering rate in strongly correlated electron systems by examining the cubic $\omega^3$ and $\omega T^2$ terms in the imaginary part of the self-energy of the Anderson impurity model. We show that the sign is opposite in the weak-coupling and strong-coupling limits, explaining the differences found in theoretical approaches taking the respective limits as the starting points. The sign change in fact precisely delineates the cross-over between the weak and strong correlation regimes of the model. For weak interaction $U$ the sign reversal occurs for small values of the doping $\delta=1-n$, while for interaction of order $U \approx 2 \Gamma$, $\Gamma$ being the hybridization strength, the cross-over curve rapidly shifts to the large-doping range. This curve based on the impurity dynamics is genuinely different from other cross-over curves defined through impurity thermodynamic and static properties.
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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.