Solving Maxwells Equations using Variational Quantum Imaginary Time Evolution
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Maxwells equations are fundamental to our understanding of electromagnetic fields, but their solution can be computationally demanding, even for high-performance computing clusters. Quantum computers offer a promising alternative for solving these equations, as they can simulate larger and more complex systems more efficiently both in time and resources. In this paper we investigate the potential of using the variational quantum imaginary time evolution (VarQITE) algorithm on near-term quantum hardware to solve for the Maxwells equations. Our objective is to analyze the trade-off between the accuracy of the simulated fields and the depth of the quantum circuit required to implement the VarQITE algorithm. We demonstrate that VarQITE can efficiently approximate the solution of these equations with high accuracy, and show that its performance can be enhanced by optimizing the quantum circuit depth. Our findings suggest that VarQITE on near-term quantum devices could provide a powerful tool for solving PDEs in electromagnetics and other fields.
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Hardware Realization of a Hamiltonian Simulation Algorithm for Time-Domain Maxwells Equations
First quantum-hardware demonstration of Hamiltonian simulation for time-domain Maxwell's equations via Schrödingerisation, with signed field measurements and agreement to classical benchmarks in 2D/3D.
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