Universal electrical transport of composite Fermi liquid to Metal transition in Moir\'e systems

Abstract

We compute universal electrical transport near continuous transitions between a composite Fermi liquid (CFL) and a metallic phase in moire Chern bands, focusing on fillings =-1/2 and =-3/4. The critical theory represents a novel QED-Chern-Simons framework: a charged sector at a bosonic Laughlin-superfluid critical point is coupled, via emergent gauge fields and Chern-Simons mixing, to a neutral spinon Fermi surface. Integrating out matter fields to quadratic order yields an explicit Ioffe-Larkin composition rule for the full resistivity tensor, showing how longitudinal channels add in series while Chern-Simons terms generate Hall response. To obtain the DC limit in the quantum critical fan, we develop a controlled large-N expansion where both fermion flavors and Chern-Simons levels scale with N, and solve a quantum Boltzmann equation at leading nontrivial order 1/N. Gauge-mediated inelastic scattering removes the collisionless Drude singularity and produces a universal scaling function (ω/T) and finite DC conductivities σ(0) ≈ 0.033 e2/ (=-1/2) and 0.047 e2/ (=-3/4). We also identify a Chern-Simons "filtering" mechanism that suppresses transmission of Landau damping from the spinon Fermi surface to the critical gauge mode. Our approach provides concrete transport diagnostics for detecting quantum criticality in moire superlattices.