Quantum Chaos and Trotterisation Thresholds in Digital Quantum Simulations

Cahit Kargi; Fabio Henriques; Lukas Sieberer; Tobias Olsacher; Philipp Hauke; Markus Heyl; Juan Pablo Dehollain; Peter Zoller; Nathan Langford

Quantum Chaos and Trotterisation Thresholds in Digital Quantum Simulations

ORAL

Abstract

Digital quantum simulation is one of the most promising paths for achieving useful real-world applications for industry-scale quantum processors. Yet even assuming continued rapid progress in device engineering, extensive resource optimisation will remain crucial to exploiting the full computational power of a device. In digital quantum simulations, Trotter step size has a profound impact on required qubit and gate numbers for each application. But contrary to standard rigorous bounds, recent theory results predict a performance threshold connecting simulation fidelity, system localisation and quantum chaos. Here, we numerically analyse several experimentally accessible digital simulation models, supporting and extending these predictions. In each case, we show that a range of numerical signatures share the same sharp threshold, at a step size that is largely independent of system size. We study in detail the relationship between the Trotterisation threshold and the onset of digitisation-induced quantum chaos. We show that chaotic dynamics can be conclusively observed down to modest system sizes, and that the same sharp threshold may even be observed in smaller systems which do not exhibit conclusive evidence of chaos.

^*Funded by Sydney Quantum Academy and an ARC Future Fellowship.

March 18, 2021, 4:24 PM – March 18, 2021, 4:36 PM

Presenters

Nathan Langford
- Centre for Quantum Software and Information & School of Mathematical and Physical Sciences, University of Technology Sydney

Authors

Cahit Kargi
- Centre for Quantum Software and Information & School of Mathematical and Physical Sciences, University of Technology Sydney
Fabio Henriques
- Centre for Quantum Software and Information & School of Mathematical and Physical Sciences, University of Technology Sydney
Lukas Sieberer
- Centre for Quantum Physics & IQOQI, University of Innsbruck & Austrian Academy of Sciences
Tobias Olsacher
- Centre for Quantum Physics & IQOQI, University of Innsbruck & Austrian Academy of Sciences
Philipp Hauke
- INO-CNR BEC Center and Department of Physics, University of Trento
- Universita di Trento
- Univ of Trento
Markus Heyl
- Max Planck Institute for the Physics of Complex Systems, Dresden
- Max Planck Institute for the Physics of Complex Systems
- Max-Planck-Institute for the Physics of Complex Systems
- Max Planck Institute for Physics of Complex Systems
Juan Pablo Dehollain
- Centre for Quantum Software and Information & School of Mathematical and Physical Sciences, University of Technology Sydney
Peter Zoller
- Centre for Quantum Physics & IQOQI, University of Innsbruck & Austrian Academy of Sciences
- University of Innsbruck
Nathan Langford
- Centre for Quantum Software and Information & School of Mathematical and Physical Sciences, University of Technology Sydney