Quantum-critical resistivity of strange metals in a magnetic field
Abstract
Resistivity in the quantum-critical fluctuation region of several metallic compounds such as the cuprates, the heavy-fermions, Fe-chalogenides and pnictides, twisted bi-layer graphene and WSe2, is linear in temperature T as well as in a magnetic field H. Scattering of fermions by the excitations of a time-reversal odd polar vector field characterizing loop-current fluctuations has been shown to give a linear in T resistivity and other anomalous properties in the cuprates. An extension of this theory to an applied magnetic field is presented. Magnetic field is shown to generate vortices in the field proportional to Hz, the component orthogonal to the conducting planes. The elastic scattering of fermions from the vortices gives a resistivity linear in Hz. The coefficient of the linear in Hz resistivity is predicted to vary as the marginal fermi-liquid susceptibility (ωcT) at criticality. Quantitative comparison with experiments is presented.
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