Local Minima in Quantum Systems
Abstract
Finding ground states of quantum many-body systems is known to be hard for both classical and quantum computers. As a result, when Nature cools a quantum system in a low-temperature thermal bath, the ground state cannot always be found efficiently. Instead, Nature finds a local minimum of the energy. In this work, we study the problem of finding local minima in quantum systems under thermal perturbations. While local minima are much easier to find than ground states, we show that finding a local minimum is computationally hard for classical computers, even when the task is to output a single-qubit observable at any local minimum. In contrast, we prove that a quantum computer can always find a local minimum efficiently using a thermal gradient descent algorithm that mimics the cooling process in Nature. To establish the classical hardness of finding local minima, we consider a family of two-dimensional Hamiltonians such that any problem solvable by polynomial-time quantum algorithms can be reduced to finding local minima of these Hamiltonians. Therefore, cooling systems to local minima is universal for quantum computation, and, assuming quantum computation is more powerful than classical computation, finding local minima is classically hard and quantumly easy.
Copyright and License
© 2024 Copyright held by the owner/author(s). This work is licensed under a Creative Commons Attribution 4.0 International License.
Acknowledgement
The authors thank Anurag Anshu, Ryan Babbush, Fernando Brandão, Garnet Chan, Sitan Chen, Soonwon Choi, Jordan Cotler, Jarrod R. McClean, and Mehdi Soleimanifar for their valuable input. HH thanks Patrick Coles, Gavin Crooks, and Faris Sbahi for the inspiring discussions and for sharing their recent works on classical thermodynamics for AI applications [5, 18]. CFC is supported by the AWS Center for Quantum Computing internship. HH is supported by a Google PhD fellowship and a MediaTek Research Young Scholarship. HH acknowledges the visiting associate position at Massachusetts Institute of Technology. LZ acknowledges funding from the Walter Burke Institute for Theoretical Physics at Caltech. JP acknowledges support from the U.S. Department of Energy Of- ce of Science, Oce of Advanced Scientic Computing Research (DE-NA0003525, DE-SC0020290), the U.S. Department of Energy, Oce of Science, National Quantum Information Science Research Centers, Quantum Systems Accelerator, and the National Science Foundation (PHY-1733907). The Institute for Quantum Information and Matter is an NSF Physics Frontiers Center.
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Additional details
- Amazon (United States)
- California Institute of Technology
- AWS Center for Quantum Computing
- Google (United States)
- MediaTek (Singapore)
- Massachusetts Institute of Technology
- California Institute of Technology
- Walter Burke Institute for Theoretical Physics
- United States Department of Energy
- DE-NA0003525
- United States Department of Energy
- DE-SC0020290
- National Science Foundation
- PHY-1733907
- Caltech groups
- Walter Burke Institute for Theoretical Physics, AWS Center for Quantum Computing, Institute for Quantum Information and Matter