Quantum simulation of Burgers turbulence: Nonlinear transformation and direct evaluation of statistical quantities
Abstract
Fault-tolerant quantum computing is a promising technology to solve linear partial differential equations that are classically demanding to integrate. It is still challenging to solve non-linear equations in fluid dynamics, such as the Burgers equation, using quantum computers. We propose a novel quantum algorithm to solve the Burgers equation. With the Cole-Hopf transformation that maps the fluid velocity field u to a new field , we apply a sequence of quantum gates to solve the resulting linear equation and obtain the quantum state that encodes the solution . We also propose an efficient way to extract stochastic properties of u, namely the multi-point functions of u, from the quantum state of . Our algorithm offers an exponential advantage over the classical finite difference method in terms of the number of spatial grids when a perturbativity condition in the information-extracting step is met.
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