Tangent Space Excitation Ansatz for Quantum Circuits

Ji-Yao Chen; Bochen Huang; D. L. Zhou; Norbert Schuch; Chenfeng Cao; Muchun Yang

doi:10.48550/arXiv.2507.07646

Tangent Space Excitation Ansatz for Quantum Circuits

Ji-Yao Chen (Corresponding author)
, Bochen Huang
, D. L. Zhou
, Norbert Schuch (Corresponding author)
, Chenfeng Cao (Corresponding author)
, Muchun Yang (Corresponding author)

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Computing excitation spectra of quantum many-body systems is a promising avenue to demonstrate the practical utility of current noisy quantum devices, especially as we move toward the “megaquop” regime. For this task, here we introduce a tangent space excitation ansatz for quantum circuits, motivated by the quasiparticle picture of many-body systems and the structural similarity between quantum circuits and tensor networks. Increasing circuit depth by one layer to construct tangent space around the variational optimum of a parametrized quantum circuit, we show that massive low-energy single-particle states can be captured. Our ansatz relies on a distinct mechanism from that of the excitation ansatz in a matrix product state and projected entangled-pair state, and avoids intrinsic limitations of the latter. Comparing our approach with existing quantum excited-state algorithms, we find that with similar computational cost, both the number of excited states and accuracy are significantly improved. We demonstrate our ansatz in both one and two dimensions, and further show that this approach, implementable using the Hadamard test, is scalable and suitable for current quantum processors.

Original language	English
Article number	150601
Number of pages	10
Journal	Physical Review Letters
Volume	136
Issue number	15
DOIs	https://doi.org/10.48550/arXiv.2507.07646 https://doi.org/10.1103/k2lc-v1hn
Publication status	Published - 17 Apr 2026

Funding

This work is supported by National Natural Science Foundation of China (Grants No. 12447107 and No. 12304186), National Key Research and Development Program of China (Grants No. 2021YFA0718302 and No. 2021YFA1402104), Guangdong Basic and Applied Basic Research Foundation (Grant No. 2024A1515013065), Guangzhou Basic and Applied Basic Research Foundation (Grant No. 2024A04J4264), the Austrian Science Fund (FWF) via Grants 10.55776/COE1 and 10.55776/F71, the European Union—NextGenerationEU, the European Union’s Horizon 2020 research and innovation programme through Grant No. 863476, and the Alexander von Humboldt Foundation.

Funders	Funder number
Fonds zur Förderung der wissenschaftlichen Forschung (FWF)	10.55776/COE1, 10.55776/F71
European Research Council	863476

Austrian Fields of Science 2012

102040 Quantum computing
103025 Quantum mechanics

Access to Document

10.48550/arXiv.2507.07646Licence: Other
10.1103/k2lc-v1hn

quantA: Quantum Science Austria
Aspelmeyer, M. (Project Lead), Arndt, M. (Co-Lead), Brukner, C. (Co-Lead), Schuch, N. (Co-Lead), Walther, P. (Co-Lead) & Nunnenkamp, A. (Co-Lead)
1/10/23 → 30/09/28
Project: Research funding
SEQUAM: Symmetries and Entanglement in Quantum Matter
Schuch, N. (Project Lead)
1/10/20 → 30/09/26
Project: Research funding
Beyond C: Quantum Information Systems Beyond Classical Capabilities
Walther, P. (Project Lead), Brukner, C. (Co-Lead), Briegel, H.-J. (Co-Lead), Kirchmair, G. (Co-Lead), Kraus, B. (Co-Lead), Lechner, W. (Co-Lead), Monz, T. (Co-Lead), Weihs, G. (Co-Lead), Roos, C. (Co-Lead), Cirac, J. I. (Co-Lead), Fink, J. (Co-Lead), Paulovics, V. (Admin), Dakic, B. (Co-Lead) & Schuch, N. (Co-Lead)
1/03/19 → 31/08/27
Project: Research funding

Cite this

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title = "Tangent Space Excitation Ansatz for Quantum Circuits",

abstract = "Computing excitation spectra of quantum many-body systems is a promising avenue to demonstrate the practical utility of current noisy quantum devices, especially as we move toward the “megaquop” regime. For this task, here we introduce a tangent space excitation ansatz for quantum circuits, motivated by the quasiparticle picture of many-body systems and the structural similarity between quantum circuits and tensor networks. Increasing circuit depth by one layer to construct tangent space around the variational optimum of a parametrized quantum circuit, we show that massive low-energy single-particle states can be captured. Our ansatz relies on a distinct mechanism from that of the excitation ansatz in a matrix product state and projected entangled-pair state, and avoids intrinsic limitations of the latter. Comparing our approach with existing quantum excited-state algorithms, we find that with similar computational cost, both the number of excited states and accuracy are significantly improved. We demonstrate our ansatz in both one and two dimensions, and further show that this approach, implementable using the Hadamard test, is scalable and suitable for current quantum processors.",

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AU - Chen, Ji-Yao

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PY - 2026/4/17

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N2 - Computing excitation spectra of quantum many-body systems is a promising avenue to demonstrate the practical utility of current noisy quantum devices, especially as we move toward the “megaquop” regime. For this task, here we introduce a tangent space excitation ansatz for quantum circuits, motivated by the quasiparticle picture of many-body systems and the structural similarity between quantum circuits and tensor networks. Increasing circuit depth by one layer to construct tangent space around the variational optimum of a parametrized quantum circuit, we show that massive low-energy single-particle states can be captured. Our ansatz relies on a distinct mechanism from that of the excitation ansatz in a matrix product state and projected entangled-pair state, and avoids intrinsic limitations of the latter. Comparing our approach with existing quantum excited-state algorithms, we find that with similar computational cost, both the number of excited states and accuracy are significantly improved. We demonstrate our ansatz in both one and two dimensions, and further show that this approach, implementable using the Hadamard test, is scalable and suitable for current quantum processors.

AB - Computing excitation spectra of quantum many-body systems is a promising avenue to demonstrate the practical utility of current noisy quantum devices, especially as we move toward the “megaquop” regime. For this task, here we introduce a tangent space excitation ansatz for quantum circuits, motivated by the quasiparticle picture of many-body systems and the structural similarity between quantum circuits and tensor networks. Increasing circuit depth by one layer to construct tangent space around the variational optimum of a parametrized quantum circuit, we show that massive low-energy single-particle states can be captured. Our ansatz relies on a distinct mechanism from that of the excitation ansatz in a matrix product state and projected entangled-pair state, and avoids intrinsic limitations of the latter. Comparing our approach with existing quantum excited-state algorithms, we find that with similar computational cost, both the number of excited states and accuracy are significantly improved. We demonstrate our ansatz in both one and two dimensions, and further show that this approach, implementable using the Hadamard test, is scalable and suitable for current quantum processors.

U2 - 10.48550/arXiv.2507.07646

DO - 10.48550/arXiv.2507.07646

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JO - Physical Review Letters

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Tangent Space Excitation Ansatz for Quantum Circuits

Abstract

Funding

Austrian Fields of Science 2012

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Projects

quantA: Quantum Science Austria

SEQUAM: Symmetries and Entanglement in Quantum Matter

Beyond C: Quantum Information Systems Beyond Classical Capabilities

Cite this