Abstract
Imaginary time evolution is a powerful tool for studying quantum systems. While it is possible to simulate with a classical computer, the time and memory requirements generally scale exponentially with the system size. Conversely, quantum computers can efficiently simulate quantum systems, but not non-unitary imaginary time evolution. We propose a variational algorithm for simulating imaginary time evolution on a hybrid quantum computer. We use this algorithm to find the ground-state energy of many-particle systems; specifically molecular hydrogen and lithium hydride, finding the ground state with high probability. Our method can also be applied to general optimisation problems and quantum machine learning. As our algorithm is hybrid, suitable for error mitigation and can exploit shallow quantum circuits, it can be implemented with current quantum computers.
Highlights
Imaginary time is an unphysical, yet powerful, mathematical concept
We have proposed a method to efficiently simulate imaginary time evolution using hybrid quantum-classical computing
We have applied our method to finding the ground-state energy of quantum systems, and have tested its performance on H2 and lithium hydride (LiH)
Summary
Imaginary time is an unphysical, yet powerful, mathematical concept. It has been utilised in numerous physical domains, including quantum mechanics, statistical mechanics and cosmology. Alternative methods are required to implement imaginary time evolution using a quantum computer. We can simulate real (imaginary) time evolution of parametrised trial states by repeatedly solving the (Wick rotated)
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