Solvable model for a dynamical quantum phase transition from fast to slow scrambling

Abstract

We propose an extension of the Sachdev-Ye-Kitaev (SYK) model that exhibits a quantum phase transition from the previously identified non-Fermi liquid fixed point to a Fermi liquid like state, while still allowing an exact solution in a suitable large N limit. The extended model involves coupling the interacting N-site SYK model to a new set of pN peripheral sites with only quadratic hopping terms between them. The conformal fixed point of the SYK model remains a stable low energy phase below a critical ratio of peripheral sites p<pc(n) that depends on the fermion filling n. The scrambling dynamics throughout the non-Fermi liquid phase is characterized by a universal Lyapunov exponent λL 2π T in the low temperature limit, however the temperature scale marking the crossover to the conformal regime vanishes continuously at the critical point pc. The residual entropy at T 0, non zero in the NFL, also vanishes continuously at the critical point. For p>pc the quadratic sites effectively screen the SYK dynamics, leading to a quadratic fixed point in the low temperature and frequency limit. The interactions have a perturbative effect in this regime leading to scrambling with Lyapunov exponent λL T2.