CSX/vol-1/no-03/Probing critical states of matter on a digital quantum computer
PTL PREMIUM
Received 19 January 2023
Reviewed 28 February 2023
Accepted 25 April 2023
Probing critical states of matter on a digital quantum computer
Reza Haghshenas
1Quantinuum, 303 S. Technology Ct., Broomfield, Colorado 80021, USA
Eli Chertkov
Matthew DeCross
Thomas M. Gatterman
Justin A. Gerber,1 Kevin Gilmore,1 Dan Gresh,1 Nathan Hewitt,1 Chandler V. Horst,1 Mitchell
Matheny,1 Tanner Mengle,1 Brian Neyenhuis,1 David Hayes,1 and Michael Foss-Feig1, †
Canadian Science Letters X
2023 ° 03(05) ° 01-03
https://www.wikipt.org/csx-home
DOI: 10.1490/6576500.983csx
Funding Agent Details
Not Applicable.
Abstract
Although quantum mechanics underpins the microscopic behaviour of all materials, its effects are often obscured at the macroscopic level by thermal fluctuations. A notable exception is a zerotemperature phase transition, where scaling laws emerge entirely due to quantum correlations over a diverging length scale. The accurate description of such transitions is challenging for classical simulation methods of quantum systems, and is a natural application space for quantum simulation. These quantum simulations are, however, not without their own challenges — representing quantum critical states on a quantum computer requires encoding entanglement of a large number of degrees of freedom, placing strict demands on the coherence and fidelity of the computer’s operations. Using Quantinuum’s H1-1 quantum computer, we address these challenges by employing hierarchical quantum tensor-network techniques, creating the ground state of the critical transverse-field Ising chain on 128-sites with sufficient fidelity to extract accurate critical properties of the model. Our results suggest a viable path to quantum-assisted tensor network contraction beyond the limits of classical methods.