Dual symplectic classical circuits: An exactly solvable model of many-body chaos

Alexios Christopoulos, Andrea De Luca, D L Kovrizhin, Tomaž Prosen
Nonlinear Sciences, Chaotic Dynamics, Chaotic Dynamics (nlin.CD), Statistical Mechanics (cond-mat.stat-mech), High Energy Physics - Theory (hep-th), Quantum Physics (quant-ph)
2023-07-03 16:00:00
We propose a general exact method of calculating dynamical correlation functions in dual symplectic brick-wall circuits in one dimension. These are deterministic classical many-body dynamical systems which can be interpreted in terms of symplectic dynamics in two orthogonal (time and space) directions. In close analogy with quantum dual-unitary circuits, we prove that two-point dynamical correlation functions are non-vanishing only along the edges of the light cones. The dynamical correlations are exactly computable in terms of a one-site Markov transfer operator, which is generally of infinite dimensionality. We test our theory in a specific family of dual-symplectic circuits, describing the dynamics of a classical Floquet spin chain. Remarkably, for these models, the rotational symmetry leads to a transfer operator with a block diagonal form on the basis of spherical harmonics. This allows us to obtain analytical predictions for simple local observables. We demonstrate the validity of our theory by comparison with Montecarlo simulations, displaying excellent agreement for different choices of observables.
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