English

Solving Quantum Ground-State Problems with Nuclear Magnetic Resonance

Quantum Physics 2011-09-12 v1

Abstract

Quantum ground-state problems are computationally hard problems; for general many-body Hamiltonians, there is no classical or quantum algorithm known to be able to solve them efficiently. Nevertheless, if a trial wavefunction approximating the ground state is available, as often happens for many problems in physics and chemistry, a quantum computer could employ this trial wavefunction to project the ground state by means of the phase estimation algorithm (PEA). We performed an experimental realization of this idea by implementing a variational-wavefunction approach to solve the ground-state problem of the Heisenberg spin model with an NMR quantum simulator. Our iterative phase estimation procedure yields a high accuracy for the eigenenergies (to the 10^-5 decimal digit). The ground-state fidelity was distilled to be more than 80%, and the singlet-to-triplet switching near the critical field is reliably captured. This result shows that quantum simulators can better leverage classical trial wavefunctions than classical computers.

Keywords

Cite

@article{arxiv.1106.0440,
  title  = {Solving Quantum Ground-State Problems with Nuclear Magnetic Resonance},
  author = {Zhaokai Li and Man-Hong Yung and Hongwei Chen and Dawei Lu and James D. Whitfield and Xinhua Peng and Alán Aspuru-Guzik and Jiangfeng Du},
  journal= {arXiv preprint arXiv:1106.0440},
  year   = {2011}
}

Comments

11 pages, 13 figures

R2 v1 2026-06-21T18:16:45.861Z