A deep dive into the interplay of structured quantum peaked circuits and infinite temperature correlation functions
- URL: http://arxiv.org/abs/2504.11240v1
- Date: Tue, 15 Apr 2025 14:41:36 GMT
- Title: A deep dive into the interplay of structured quantum peaked circuits and infinite temperature correlation functions
- Authors: Myeongsu Kim, Manas Sajjan, Sabre Kais,
- Abstract summary: We propose the infinite-temperature correlation function (ITCF) as a physically meaningful observable for noisy quantum devices.<n>We construct purposefully biased quantum states using either Grover-based amplitude amplification or shallow structured circuits.<n>Our results highlight a problem-specific state preparation framework that mitigates signal loss from random averaging.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Random quantum circuits have been extensively explored for quantum supremacy demonstrations. However, verifying their output distributions remains challenging. Here, we propose the infinite-temperature correlation function (ITCF) as a physically meaningful observable for noisy intermediate-scale quantum (NISQ) devices one that can be extracted using engineered circuits rather than relying on fully random constructions. This is realized by leveraging peaked quantum states whose probability distributions are sharply peaked at specific outcomes due to constructive interference thus offering more efficient verifiability and stronger signal observability. Rather than using Haar-random states, which often yield vanishing signals through destructive interference, we construct purposefully biased quantum states using either Grover-based amplitude amplification or shallow structured circuits. These engineered states amplify contributions from relevant operator subspaces, enabling robust detection of non-zero ITCF values that would otherwise be suppressed under random-state sampling. Our results highlight a problem-specific state preparation framework that mitigates signal loss from random averaging and facilitates the detection of physically meaningful observables in NISQ devices. We also discuss future extensions to multi-qubit observables, scrambling diagnostics, and variational circuit optimization, underscoring the broader potential of Peaked States for quantum simulation and verification.
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