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Autori principali: Li, Keren, Lin, Zidong, An, Zheng, Feng, Guanru, Wu, Zipeng, Hou, Shiyao, Xiang, Jingen
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2511.05436
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author Li, Keren
Lin, Zidong
An, Zheng
Feng, Guanru
Wu, Zipeng
Hou, Shiyao
Xiang, Jingen
author_facet Li, Keren
Lin, Zidong
An, Zheng
Feng, Guanru
Wu, Zipeng
Hou, Shiyao
Xiang, Jingen
contents Scaling up quantum devices is a central challenge for realizing practical quantum computation. Modular quantum architectures promise scalability, yet experiments to date have relied on either $\sim\!10^{3}$-qubit monolithic chips or fragile interconnects with high loss. Here, we introduce a classical linkage scheme that merges multiple independent quantum processing units (QPUs) into a single logical device, enabling thread-level parallelism (TLP). Theoretically, we show that quantum routines with product-state inputs and low-rank entangling layers can be re-expressed in an efficient parallelizable form. Experimentally, we validate this architecture on clusters comprising up to sixteen benchtop nuclear magnetic resonance (NMR) quantum nodes. A four-qubit Greenberger-Horne-Zeilinger (GHZ) state is partitioned into parallel two-qubit subcircuits, achieving a fidelity of $93.8\,\%$ with respect to the ideal state. A non-Hermitian evolution, implemented via a truncated Cauchy integral on Hermitian Hamiltonians, reproduces exact observables with high accuracy. Our results demonstrate that classical links suffice to scale up the logical size of quantum computations and realize general, non-unitary channels on today's hardware, opening an experimentally accessible route toward software-defined, clustered quantum accelerators.
format Preprint
id arxiv_https___arxiv_org_abs_2511_05436
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Realization of Thread Level Parallelism on Quantum Devices
Li, Keren
Lin, Zidong
An, Zheng
Feng, Guanru
Wu, Zipeng
Hou, Shiyao
Xiang, Jingen
Quantum Physics
Scaling up quantum devices is a central challenge for realizing practical quantum computation. Modular quantum architectures promise scalability, yet experiments to date have relied on either $\sim\!10^{3}$-qubit monolithic chips or fragile interconnects with high loss. Here, we introduce a classical linkage scheme that merges multiple independent quantum processing units (QPUs) into a single logical device, enabling thread-level parallelism (TLP). Theoretically, we show that quantum routines with product-state inputs and low-rank entangling layers can be re-expressed in an efficient parallelizable form. Experimentally, we validate this architecture on clusters comprising up to sixteen benchtop nuclear magnetic resonance (NMR) quantum nodes. A four-qubit Greenberger-Horne-Zeilinger (GHZ) state is partitioned into parallel two-qubit subcircuits, achieving a fidelity of $93.8\,\%$ with respect to the ideal state. A non-Hermitian evolution, implemented via a truncated Cauchy integral on Hermitian Hamiltonians, reproduces exact observables with high accuracy. Our results demonstrate that classical links suffice to scale up the logical size of quantum computations and realize general, non-unitary channels on today's hardware, opening an experimentally accessible route toward software-defined, clustered quantum accelerators.
title Realization of Thread Level Parallelism on Quantum Devices
topic Quantum Physics
url https://arxiv.org/abs/2511.05436