Related papers: Highly-entangled, highly-doped states that are efficiently cross-device verifiable

Highly-entangled, highly-doped states that are efficiently cross-device verifiable

URL: http://arxiv.org/abs/2501.11688v1
Date: Mon, 20 Jan 2025 19:12:34 GMT
Title: Highly-entangled, highly-doped states that are efficiently cross-device verifiable
Authors: Janek Denzler, Santiago Varona, Tommaso Guaita, Jose Carrasco,
Abstract summary: We introduce a class of highly entangled real quantum states that cannot be approximated by circuits with $log$-many non-Clifford gates. We prove that Bell sampling enables efficient cross-device verification (or distributed inner product estimation) for these states. We anticipate that these results could have applications in quantum cryptography and verification.
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Abstract: In this paper, we introduce a class of highly entangled real quantum states that cannot be approximated by circuits with $\log$-many non-Clifford gates and prove that Bell sampling enables efficient cross-device verification (or distributed inner product estimation) for these states. That is, two remote parties can estimate the inner product ${\rm tr}(\rho\sigma)$, each having black-box access to copies of a state $\rho$ (or respectively $\sigma$) in this class. This is significant because it is clear that this task can be achieved in those cases (such as low entanglement or low non-Clifford gate count) where one can independently learn efficient classical descriptions of each state using established techniques and share the description to compute the overlap. Instead, our results demonstrate that this is possible even in more complex scenarios where these "learn and share" methods are insufficient. Our proposal is scalable, as it just requires a number of two-copy Bell measurements and single-copy Pauli measurements that grows polynomially with both the number of qubits and the desired inverse-error, and can be implemented in the near term. Moreover, the required number of samples can be efficiently experimentally determined by the parties in advance, and our findings are robust against preparation errors. We anticipate that these results could have applications in quantum cryptography and verification.

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