A Quantum Algorithm for Nonlinear Electromagnetic Fluid Dynamics via Koopman-von Neumann Linearization

Abstract

To simulate plasma phenomena, large-scale computational resources have been employed in developing high-precision and high-resolution plasma simulations. One of the main obstacles in plasma simulations is the requirement of computational resources that scale polynomially with the number of spatial grids, which poses a significant challenge for large-scale modeling. To address this issue, this study presents a quantum algorithm for simulating the nonlinear electromagnetic fluid dynamics that govern space plasmas. We map it, by applying Koopman-von Neumann linearization, to the Schr\"odinger equation and evolve the system using Hamiltonian simulation via quantum singular value transformation. Our algorithm scales O (s Nx \, polylog ( Nx ) T ) in time complexity with s, Nx, and T being the spatial dimension, the number of spatial grid points per dimension, and the evolution time, respectively. Comparing the scaling O ( s Nxs (T5/4+T Nx) ) for the classical method with the finite volume scheme, this algorithm achieves polynomial speedup in Nx. The space complexity of this algorithm is exponentially reduced from O( s Nxs ) to O( s \, polylog ( Nx ) ). Numerical experiments validate that accurate solutions are attainable with smaller m than theoretically anticipated and with practical values of m and R, underscoring the feasibility of the approach. As a practical demonstration, the method accurately reproduces the Kelvin-Helmholtz instability, underscoring its capability to tackle more intricate nonlinear dynamics. These results suggest that quantum computing can offer a viable pathway to overcome the computational barriers of multiscale plasma modeling.