Generation of thermofield double states and critical ground states with a quantum computer

Zhu, Daiwei; Johri, Sonika; Linke, Norbert; Landsman, K. A.; Alderete, C. Huerta; Nguyen, Nhung H.; Matsuura, A. Y.; Hsieh, Timothy H.; Monroe, C.

doi:10.1073/pnas.2006337117

Cited by 100 publications

(89 citation statements)

References 42 publications

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“…Furthermore, using both CV and CA, holographic complexity was found to grow quadratically C ∼ t 2 at early times due to the time-reversal symmetry of the charged black hole geometry. 35 Finally, the rate of change in complexity was found to vanish at all times in the extremal (vanishing temperature) limit using both the CV and the CA complexity proposals. Our analysis of the cTFD in the previous section resulted in the following features which can be tested for consistency and qualitatively compared to the holographic results.…”

Section: Jhep02(2021)187mentioning

confidence: 95%

“…charged black holes whose horizon radius is much larger, or of the same order as the AdS scale. 35 The charged case smoothly interpolates to the neutral case, where CA interestingly gives a neighbourhood around t = 0 where the rate of change in holographic complexity is exactly zero, then discontinuously becomes infinitely negative, only to quickly grow to a positive value in a short time [39].…”

Section: Jhep02(2021)187mentioning

confidence: 97%

“…TFD and cTFD states received special attention in holographic studies due to their duality to (neutral and charged) eternal black holes of the corresponding temperature [30] and chemical potential [31,32]. Outside the context of holography, a number of works have been written on building the TFD state in the laboratory [33][34][35][36][37] and these further motivate focusing on the TFD for simple quantum mechanical systems. Since charge is very natural in an experimental setup, we expect that the cTFD state is also a natural state to study in the laboratory.…”

Section: Jhep02(2021)187mentioning

confidence: 99%

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Charged complexity and the thermofield double state

Chapman

Chen

2021

J. High Energ. Phys.

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We establish a systematic framework for studying quantum computational complexity of Gaussian states of charged systems based on Nielsen’s geometric approach. We use this framework to examine the effect of a chemical potential on the dynamics of complexity. As an example, we consider the complexity of a charged thermofield double state constructed from two free massive complex scalar fields in the presence of a chemical potential. We show that this state factorizes between positively and negatively charged modes and demonstrate that this fact can be used to relate it, for each momentum mode separately, to two uncharged thermofield double states with shifted temperatures and times. We evaluate the complexity of formation for the charged thermofield double state, both numerically and in certain analytic expansions. We further present numerical results for the time dependence of complexity. We compare various aspects of these results to those obtained in holography for charged black holes.

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Section: Jhep02(2021)187mentioning

confidence: 95%

Section: Jhep02(2021)187mentioning

confidence: 97%

Section: Jhep02(2021)187mentioning

confidence: 99%

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Charged complexity and the thermofield double state

Chapman

Chen

2021

J. High Energ. Phys.

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“…For finite temperature state, one could use the algorithms discussed in[95,96,114] to prepare thermofield double states.…”

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confidence: 99%

Toward simulating superstring/M-theory on a quantum computer

Gharibyan

Hanada

Honda

et al. 2021

J. High Energ. Phys.

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We present a novel framework for simulating matrix models on a quantum computer. Supersymmetric matrix models have natural applications to superstring/M-theory and gravitational physics, in an appropriate limit of parameters. Furthermore, for certain states in the Berenstein-Maldacena-Nastase (BMN) matrix model, several supersymmetric quantum field theories dual to superstring/M-theory can be realized on a quantum device. Our prescription consists of four steps: regularization of the Hilbert space, adiabatic state preparation, simulation of real-time dynamics, and measurements. Regularization is performed for the BMN matrix model with the introduction of energy cut-off via the truncation in the Fock space. We use the Wan-Kim algorithm for fast digital adiabatic state preparation to prepare the low-energy eigenstates of this model as well as thermofield double state. Then, we provide an explicit construction for simulating real-time dynamics utilizing techniques of block-encoding, qubitization, and quantum signal processing. Lastly, we present a set of measurements and experiments that can be carried out on a quantum computer to further our understanding of superstring/M-theory beyond analytic results.

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“…Here, we demonstrate a cross-platform comparison based on randomized-measurement [8][9][10] , obtained independently over different times and locations on several disparate quantum computers built by different teams using different technologies, comparing the outcomes of four families of quantum circuits. We use four ion-trap platforms, the University of Maryland (UMD) EU-RIQA system 11 (referred to as UMD 1), the University of Maryland TIQC system 12 (UMD 2), and two IonQ quantum computers 13,14 (IonQ 1, IonQ 2), as well as five separate IBM superconducting quantum computing systems hosted in New York, ibmq belem (IBM 1), ibmq casablanca (IBM 2), ibmq melbourne (IBM 3), ibmq quito (IBM 4), and ibmq rome (IBM 5) 15 . See Supplementary Information Sec.…”

mentioning

confidence: 99%

Cross-Platform Comparison of Arbitrary Quantum Computations

Zhu

Cian

Noel

et al. 2021

Preprint

Self Cite

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As we approach the era of quantum advantage, when quantum computers (QCs) can outperform any classical computer on particular tasks, there remains the difficult challenge of how to validate their performance. While algorithmic success can be easily verified in some instances such as number factoring or oracular algorithms, these approaches only provide pass/fail information for a single QC. On the other hand, a comparison between different QCs on the same arbitrary circuit provides a lower-bound for generic validation: a quantum computation is only as valid as the agreement between the results produced on different QCs. Such an approach is also at the heart of evaluating metrological standards such as disparate atomic clocks. In this paper, we report a cross-platform QC comparison using randomized and correlated measurements that results in a wealth of information on the QC systems. We execute several quantum circuits on widely different physical QC platforms and analyze the cross-platform fidelities.

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Generation of thermofield double states and critical ground states with a quantum computer

Cited by 100 publications

References 42 publications

Charged complexity and the thermofield double state

Charged complexity and the thermofield double state

Toward simulating superstring/M-theory on a quantum computer

Cross-Platform Comparison of Arbitrary Quantum Computations

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