Arquiteturas Modulares e Redes Quânticas: Um estudo da atualidade por meio de revisão bibliográfica

Tarcisio de Souza Peres; Cláudio Boghi

doi:10.33448/rsd-v14i12.50156

Authors

Tarcisio de Souza Peres Universidade Paulista https://orcid.org/0009-0009-2801-0896
Cláudio Boghi Universidade Paulista https://orcid.org/0000-0002-7974-6416

DOI:

https://doi.org/10.33448/rsd-v14i12.50156

Keywords:

Quantum computing, Hardware, Computational architecture, Qubits.

Abstract

The physical and engineering limitations of current quantum devices are driving the development of modular architectures and quantum networks to enable large-scale quantum computers. This article aims to present a literature review on modular architectures in quantum computing. The study aims to present and discuss the main hardware platforms—including superconducting qubits, trapped ions, neutral atoms, and photonic qubits—and analyze how quantum modules can be interconnected with distributed entanglement methods, quantum repeaters, and logic gate teleportation, as well as cost and latency models for distributed quantum operations. Scalability aspects and practical physical implementation challenges are examined in light of proposals and case studies of real modular architectures, such as the IonQ and Honeywell (Quantinuum) approaches with trapped ions and Xanadu with photonics. Finally, we compare the approaches of different platforms and discuss ways to overcome technical obstacles toward modularly scalable and fault-tolerant quantum computers.

References

Awschalom, D. et al. (2021). Quantum interconnects for the long-distance quantum internet. PRX Quantum. 2, 017002.

Brown, K. R., Kim, J. & Monroe, C. (2016). Co-designing a scalable quantum computer with trapped atomic ions. NPJ Quantum Information. 2, 16034.

Bushman, J. (2025). Parallel atom-photon entanglement paves way for future quantum networking. The Grainger College of Engineering (University of Illinois Urbana-Champaign). https://grainger.illinois.edu/news/stories/77824.

Cantori, S., Pfaffhauser, M., Bäumer, E., Scafirimuto, F. & Davis, R. (2025). Using dynamic circuits to efficiently implement quantum states with long-range entanglement. IBM Quantum Computing Blog. https://www.ibm.com/quantum/blog/long-range-entanglement.

Chen, Y. et al. (2021). (Google Quantum AI). Exponential suppression of bit or phase errors with cyclic error correction. Nature. 595, 383–7.

Covey, J. P., Weinfurter, H. & Bernien, H. (2023). Quantum networks with neutral atom processing nodes. NPJ Quantum Information. 9(90).

Gold, A. et al. (2021). Entanglement across separate silicon dies in a modular superconducting qubit device. NPJ Quantum Information. 7(1), 142.

Hucul, D. et al. (2015). Modular entanglement of atomic qubits using both photons and phonons. Nature Physics. 11, 37‑42

Krutyanskiy, V. et al. (2023). Entanglement of trapped-ion qubits separated by 230 meters. Phys. Rev. Lett. 130, 050803.

Li, X‑G. et al. (2025). Direct evidence for cosmic‑ray‑induced correlated errors in superconducting qubit array. Nature Communications. 16, 4677.

Madsen, L. S. et al. (2022). Quantum computational advantage with a programmable photonic processor. Nature. 606(7912), 75-81.

Matsukevich, D. N. et al. (2006). Distribution of entanglement using photons and phonons in a crystal network. Science. 311, 1008-12.

Monroe, C. et al. (2014). Large-scale modular quantum-computer architecture with atomic memory and photonic interconnects. Phys. Rev. A. 89, 022317.

Monroe, C. (2014). Modular Entanglement of Atoms. Quantum Computing with Trapped Ions.

https://iontrap.duke.edu/2014/11/17/modular-entanglement-of-atoms/.

Nickerson, N. H., Fitzsimons, J. F. & Benjamin, S. C. (2014). Freely scalable quantum technologies using cells of 5-to-50 qubits with very lossy and noisy photonic links. Phys. Rev. X. 4, 041041.

Niu, J. et al. (2023). Low-loss interconnects for modular superconducting quantum processors. Nature Electronics. 6(3), 235-41.

Pereira, A. S., Shitsuka, D. M., Parreira, F. J. & Shitsuka, R. (2018). Metodologia da Pesquisa Científica. Santa Maria: Editora da UFSM

Pino, J. M. et al. (2021). Demonstration of the trapped-ion quantum CCD computer architecture. Nature. 592, 209–13.

Snyder, H. (2019). Literature review as a research methodology: An overview and guidelines. Journal of Business Research. 104, 333–9.

Rother, E. T. (2007). Revisão sistemática versus revisão narrativa. Acta Paulista de Enfermagem, São Paulo. 20(2), v–vi.

Sunami, S. et al. (2025). Scalable networking of neutral-atom qubits: Nanofiber-based approach for multiprocessor fault-tolerant quantum computers. PRX Quantum. 6, 010101.

Xanadu (C. Weedbrook). (2025). Press Release: Xanadu announces Aurora, a universal photonic quantum computer with a modular architecture. The Quantum Insider.

Modular Architectures and Quantum Networks: A current study through bibliographic review

Authors

DOI:

Keywords:

Abstract

References

Downloads

Published

Issue

Section

License

How to Cite

Language

Make a Submission

impcatfactor

JOURNAL METRICS