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Digitization of Scalar Fields for Quantum Computing

Quantum Physics 2019-05-28 v2 High Energy Physics - Lattice High Energy Physics - Phenomenology Nuclear Theory

Abstract

Qubit, operator and gate resources required for the digitization of lattice λϕ4\lambda\phi^4 scalar field theories onto quantum computers are considered, building upon the foundational work by Jordan, Lee and Preskill, with a focus towards noisy intermediate-scale quantum (NISQ) devices. The Nyquist-Shannon sampling theorem, introduced in this context by Macridin, Spentzouris, Amundson and Harnik building on the work of Somma, provides a guide with which to evaluate the efficacy of two field-space bases, the eigenstates of the field operator, as used by Jordan, Lee and Preskill, and eigenstates of a harmonic oscillator, to describe 0+10+1- and d+1d+1-dimensional scalar field theory. We show how techniques associated with improved actions, which are heavily utilized in Lattice QCD calculations to systematically reduce lattice-spacing artifacts, can be used to reduce the impact of the field digitization in λϕ4\lambda\phi^4, but are found to be inferior to a complete digitization-improvement of the Hamiltonian using a Quantum Fourier Transform. When the Nyquist-Shannon sampling theorem is satisfied, digitization errors scale as loglogϵdignQ|\log|\log |\epsilon_{\rm dig}|||\sim n_Q (number of qubits describing the field at a given spatial site) for the low-lying states, leaving the familiar power-law lattice-spacing and finite-volume effects that scale as logϵlattNQ|\log |\epsilon_{\rm latt}||\sim N_Q (total number of qubits in the simulation). For localized(delocalized) field-space wavefunctions, it is found that nQ4(7)n_Q\sim4(7) qubits per spatial lattice site are sufficient to reduce theoretical digitization errors below error contributions associated with approximation of the time-evolution operator and noisy implementation on near-term quantum devices.

Keywords

Cite

@article{arxiv.1808.10378,
  title  = {Digitization of Scalar Fields for Quantum Computing},
  author = {Natalie Klco and Martin J. Savage},
  journal= {arXiv preprint arXiv:1808.10378},
  year   = {2019}
}

Comments

48 pages, 19 figures, 4 tables

R2 v1 2026-06-23T03:49:26.114Z