Planckian metal at a doping-induced quantum critical point

We numerically study a model of interacting spin-1/2 electrons with random exchange coupling on a fully connected lattice. This model hosts a quantum critical point separating two distinct metallic phases as a function of doping: a Fermi-liquid phase with a large Fermi-surface volume and a low-doping phase with local moments ordering into a spin glass. We show that this quantum critical point has non-Fermi-liquid properties characterized by T-linear Planckian behavior, /T scaling, and slow spin dynamics of the Sachdev-Ye-Kitaev type. The /T scaling function associated with the electronic self-energy is found to have an intrinsic particle-hole asymmetry, a hallmark of a ``skewed'' non-Fermi liquid.