Going Beyond Gadgets: The Importance of Scalability for Analogue Quantum Simulators

Research output: Working paperPreprintResearch

Standard

Going Beyond Gadgets : The Importance of Scalability for Analogue Quantum Simulators. / Harley, Dylan; Datta, Ishaun; Klausen, Frederik Ravn; Bluhm, Andreas; Stilck França, Daniel; Werner, Albert H.; Christandl, Matthias.

arXiv.org, 2023.

Research output: Working paperPreprintResearch

Harvard

Harley, D, Datta, I, Klausen, FR, Bluhm, A, Stilck França, D, Werner, AH & Christandl, M 2023 'Going Beyond Gadgets: The Importance of Scalability for Analogue Quantum Simulators' arXiv.org. <https://arxiv.org/abs/2306.13739>

APA

Harley, D., Datta, I., Klausen, F. R., Bluhm, A., Stilck França, D., Werner, A. H., & Christandl, M. (2023). Going Beyond Gadgets: The Importance of Scalability for Analogue Quantum Simulators. arXiv.org. https://arxiv.org/abs/2306.13739

Vancouver

Harley D, Datta I, Klausen FR, Bluhm A, Stilck França D, Werner AH et al. Going Beyond Gadgets: The Importance of Scalability for Analogue Quantum Simulators. arXiv.org. 2023.

Author

Harley, Dylan ; Datta, Ishaun ; Klausen, Frederik Ravn ; Bluhm, Andreas ; Stilck França, Daniel ; Werner, Albert H. ; Christandl, Matthias. / Going Beyond Gadgets : The Importance of Scalability for Analogue Quantum Simulators. arXiv.org, 2023.

Bibtex

@techreport{9c8912ba531b47a5933aad4e2789eb72,
title = "Going Beyond Gadgets: The Importance of Scalability for Analogue Quantum Simulators",
abstract = "We propose a theoretical framework for analogue quantum simulation to capture the full scope of experimentally realisable simulators, motivated by a set of fundamental criteria first introduced by Cirac and Zoller. Our framework is consistent with Hamiltonian encodings used in complexity theory, is stable under noise, and encompasses a range of possibilities for experiment, such as the simulation of open quantum systems and overhead reduction using Lieb-Robinson bounds. We discuss the requirement of scalability in analogue quantum simulation, and in particular argue that simulation should not involve interaction strengths that grow with the size of the system. We develop a general framework for gadgets used in Hamiltonian complexity theory, which may be of interest independently of analogue simulation, and in particular prove that size-dependent scalings are unavoidable in Hamiltonian locality reduction. However, if one allows for an additional resource of engineered dissipation, we demonstrate a scheme that circumvents the locality reduction no-go theorem using the quantum Zeno effect. Our gadget framework opens the door to formalise and resolve long-standing open questions about gadgets. We conclude with a discussion on universality results in analogue quantum simulation. ",
author = "Dylan Harley and Ishaun Datta and Klausen, {Frederik Ravn} and Andreas Bluhm and {Stilck Fran{\c c}a}, Daniel and Werner, {Albert H.} and Matthias Christandl",
year = "2023",
language = "English",
publisher = "arXiv.org",
type = "WorkingPaper",
institution = "arXiv.org",

}

RIS

TY - UNPB

T1 - Going Beyond Gadgets

T2 - The Importance of Scalability for Analogue Quantum Simulators

AU - Harley, Dylan

AU - Datta, Ishaun

AU - Klausen, Frederik Ravn

AU - Bluhm, Andreas

AU - Stilck França, Daniel

AU - Werner, Albert H.

AU - Christandl, Matthias

PY - 2023

Y1 - 2023

N2 - We propose a theoretical framework for analogue quantum simulation to capture the full scope of experimentally realisable simulators, motivated by a set of fundamental criteria first introduced by Cirac and Zoller. Our framework is consistent with Hamiltonian encodings used in complexity theory, is stable under noise, and encompasses a range of possibilities for experiment, such as the simulation of open quantum systems and overhead reduction using Lieb-Robinson bounds. We discuss the requirement of scalability in analogue quantum simulation, and in particular argue that simulation should not involve interaction strengths that grow with the size of the system. We develop a general framework for gadgets used in Hamiltonian complexity theory, which may be of interest independently of analogue simulation, and in particular prove that size-dependent scalings are unavoidable in Hamiltonian locality reduction. However, if one allows for an additional resource of engineered dissipation, we demonstrate a scheme that circumvents the locality reduction no-go theorem using the quantum Zeno effect. Our gadget framework opens the door to formalise and resolve long-standing open questions about gadgets. We conclude with a discussion on universality results in analogue quantum simulation.

AB - We propose a theoretical framework for analogue quantum simulation to capture the full scope of experimentally realisable simulators, motivated by a set of fundamental criteria first introduced by Cirac and Zoller. Our framework is consistent with Hamiltonian encodings used in complexity theory, is stable under noise, and encompasses a range of possibilities for experiment, such as the simulation of open quantum systems and overhead reduction using Lieb-Robinson bounds. We discuss the requirement of scalability in analogue quantum simulation, and in particular argue that simulation should not involve interaction strengths that grow with the size of the system. We develop a general framework for gadgets used in Hamiltonian complexity theory, which may be of interest independently of analogue simulation, and in particular prove that size-dependent scalings are unavoidable in Hamiltonian locality reduction. However, if one allows for an additional resource of engineered dissipation, we demonstrate a scheme that circumvents the locality reduction no-go theorem using the quantum Zeno effect. Our gadget framework opens the door to formalise and resolve long-standing open questions about gadgets. We conclude with a discussion on universality results in analogue quantum simulation.

M3 - Preprint

BT - Going Beyond Gadgets

PB - arXiv.org

ER -

ID: 382558304