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Abstract

Time-periodic quantum systems exhibit a rich variety of far-from-equilibrium phenomena and serve as ideal platforms for quantum engineering and control. However, simulating their dynamics with conventional numerical methods remains challenging due to the exponential growth of Hilbert space dimension and rapid spreading of entanglement. In this work, we introduce Fourier Neural Operators (FNO) as an efficient, accurate, and scalable surrogate for non-equilibrium quantum dynamics. Parameterized in Fourier space, FNO naturally captures temporal correlations and remains minimally dependent on discretization of time. We demonstrate the versatility of FNO through three complementary learning paradigms: reconstructing effective Floquet Hamiltonians, predicting expectation values of local observables, and learning quantum information spreading. For each learning task, FNO achieves remarkable accuracy, while attaining a significant speedup, compared to exact numerical methods. Moreover, FNO possesses a remarkable capacity to transfer learning across different temporal discretizations and system driving frequencies. We also show that FNO can extrapolate beyond the time window provided by training data, enabling access to observables and operator-spreading dynamics that might otherwise be difficult to obtain. By employing an appropriate local basis, we argue that the computational cost of FNOs scales only polynomially with the system size. Our results establish FNO as a versatile and scalable surrogate for predicting non-equilibrium quantum dynamics, with potential applications to processing data from near-term quantum computers.