Gauge-Symmetry Protection Using Single-Body Terms
Year: 2021
Authors: Halimeh J.C., Lang H., Mildenberger J., Jiang Z., Hauke P.
Autors Affiliation: INO-CNR BEC Center, Department of Physics, University of Trento, via Sommarive 14, Trento, I-38123, INO-CNR BEC Center and Department of Physics, University of Trento, via Sommarive 14, Trento I-38123, Italy, , , Italy; INO-CNR BEC Center, Department of Physics, University of Trento, via Sommarive 14, Trento, I-38123, INO-CNR BEC Center and Department of Physics, University of Trento, via Sommarive 14, Trento I-38123, Italy, , , Italy; Theoretical Chemistry, Institute of Physical Chemistry, Heidelberg University, Im Neuenheimer Feld 229, Heidelberg, 69120, Theoretical Chemistry, Institute of Physical Chemistry, Heidelberg University, Im Neuenheimer Feld 229, Heidelberg 69120, Germany, , Germany; Google AI Quantum, Venice, CA, Google AI Quantum, Venice, California, USA, , United States
Abstract: Quantum-simulator hardware promises new insights into problems from particle and nuclear physics. A major challenge is to reproduce gauge invariance, as violations of this quintessential property of lattice gauge theories can have dramatic consequences, e.g., the generation of a photon mass in quantum electrodynamics. Here, we introduce an experimentally friendly method to protect gauge invariance in U(1) lattice gauge theories against coherent errors in a controllable way. Our method employs only single-body energy-penalty terms, thus enabling practical implementations. As we derive analytically, some sets of penalty coefficients render undesired gauge sectors inaccessible by unitary dynamics for exponentially long times. Further, for few-body error terms, we show numerically that this is achieved with resources exhibiting little dependence on system size. These findings constitute an exponential improvement over previously known results from energy-gap protection or perturbative treatments. In our method, the gauge-invariant subspace is protected by an emergent global symmetry, meaning it can be immediately applied to other symmetries. In our numerical benchmarks for continuous-time and digital quantum simulations, gauge protection holds for all calculated evolution times (up to t>1010/J for continuous time, with J the relevant energy scale). Crucially, our gauge-protection technique is simpler to realize than the associated ideal gauge theory, and can thus be readily implemented in current ultracold-atom analog simulators as well as digital noisy intermediate-scale quantum devices.
Journal/Review: PRX QUANTUM
Volume: 2 (4) Pages from: 040311-19 to: 040311-19
KeyWords: periodically driven; quantum simulation; python framework; dynamics; invarianceDOI: 10.1103/PRXQuantum.2.040311