English

Numerical Engineering of Robust Adiabatic Operations

Quantum Physics 2021-05-04 v2

Abstract

Adiabatic operations are powerful tools for robust quantum control in numerous fields of physics, chemistry and quantum information science. The inherent robustness due to adiabaticity can, however, be impaired in applications requiring short evolution times. We present a single versatile gradient-based optimization protocol that combines adiabatic control with effective Hamiltonian engineering in order to design adiabatic operations tailored to the specific imperfections and resources of an experimental setup. The practicality of the protocol is demonstrated by engineering a fast, 2.3 Rabi cycle-long adiabatic inversion pulse for magnetic resonance with built-in robustness to Rabi field inhomogeneities and resonance offsets. The performance and robustness of the pulse is validated in a nanoscale force-detected magnetic resonance experiment on a solid-state sample, indicating an ensemble-averaged inversion accuracy of 99.997%\sim 99.997\%. We further showcase the utility of our protocol by providing examples of adiabatic pulses robust to spin-spin interactions, parameter-selective operations and operations connecting arbitrary states, each motivated by experiments.

Keywords

Cite

@article{arxiv.2009.03266,
  title  = {Numerical Engineering of Robust Adiabatic Operations},
  author = {Sahand Tabatabaei and Holger Haas and William Rose and Ben Yager and Michèle Piscitelli and Pardis Sahafi and Andrew Jordan and Philip J. Poole and Dan Dalacu and Raffi Budakian},
  journal= {arXiv preprint arXiv:2009.03266},
  year   = {2021}
}

Comments

Main text: 14 pages, 6 figures; supplemental material: 6 pages, 2 figures

R2 v1 2026-06-23T18:22:10.113Z