Related papers: Standardized test of many-body coherence in gate-based quantum platforms

Standardized test of many-body coherence in gate-based quantum platforms

URL: http://arxiv.org/abs/2503.12573v1
Date: Sun, 16 Mar 2025 17:01:14 GMT
Title: Standardized test of many-body coherence in gate-based quantum platforms
Authors: Yi Teng, Orazio Scarlatella, Shiyu Zhou, Armin Rahmani, Claudio Chamon, Claudio Castelnovo,
Abstract summary: We propose a method to define a many-body quantum coherence length scale using anyon interference effects in a spin-chain setup.<n>We demonstrate how this approach can be implemented on gate-based quantum platforms to estimate and compare the quantum coherence of current devices.
Score: 3.983816213148414
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Quantum coherence is a crucial resource in achieving quantum advantage over classical information processing, and more generally developing new quantum technologies. While its effects are observable in current quantum platforms, there are no standardized tools for systematically measuring and quantifying multi-qubit coherence across different gate-based quantum hardware. In this work, we propose a method to define a many-body quantum coherence length scale using anyon interference effects in a spin-chain setup, which effectively mirrors the problem of a quantum particle on a ring, with or without flux through it. We propose using the maximum length of the ring for which the presence or absence of flux can be clearly discerned, as a simple measure of the many-body quantum coherence grade (Q-grade) in a given quantum hardware. We demonstrate how this approach can be implemented on gate-based quantum platforms to estimate and compare the quantum coherence of current devices, such as those from Google, IBM, IonQ, IQM, and Quantinuum that we considered here. This work aims to contribute to the creation of a live Web interface where the latest developments and advancements can be demonstrated, and progress in quantum coherence resources tracked over time. Establishing such a standardized quantum test would enable monitoring the growth of quantum coherence in gate-based quantum platforms, in a spirit similar to Moore's law.

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