A minimal model of electrons coupled to quantum critical bosons through disordered Yukawa interactions and pinned density waves derives T-linear and B-linear transport scalings that match strange metal experiments.
Extended strange metal regime from super- conducting puddles,
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Neutron scattering reveals dynamical scaling of critical spin fluctuations across the LSCO superconducting dome, consistent with a disordered spin density wave quantum phase transition explaining strange metal behavior.
Reviews the FL* theory for cuprates using ancilla layer models and SU(2) gauge theories to explain pseudogap hole pockets of area p/8, Fermi arcs, and transitions to d-wave superconductivity and Fermi liquid behavior.
citing papers explorer
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Theory of Linear Magnetoresistance in a Strange Metal
A minimal model of electrons coupled to quantum critical bosons through disordered Yukawa interactions and pinned density waves derives T-linear and B-linear transport scalings that match strange metal experiments.
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Critical spin fluctuations across the superconducting dome in La$_{2-x}$Sr$_{x}$CuO$_4$
Neutron scattering reveals dynamical scaling of critical spin fluctuations across the LSCO superconducting dome, consistent with a disordered spin density wave quantum phase transition explaining strange metal behavior.
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Fractionalized Fermi liquids and the cuprate phase diagram
Reviews the FL* theory for cuprates using ancilla layer models and SU(2) gauge theories to explain pseudogap hole pockets of area p/8, Fermi arcs, and transitions to d-wave superconductivity and Fermi liquid behavior.