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CSX/vol-1/no-03/Probing critical states of matter on a digital quantum computer

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PTL PREMIUM

Received 19 January 2023
Reviewed 28 February 2023
Accepted 25 April 2023

Probing critical states of matter on a digital quantum computer

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Reza Haghshenas
1Quantinuum, 303 S. Technology Ct., Broomfield, Colorado 80021, USA

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Eli Chertkov

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Matthew DeCross

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Thomas M. Gatterman

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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.

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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.



 





Introduction