Related papers: Multiple Quantum Many-Body Clustering Probed by Dynamical Decoupling

Multiple Quantum Many-Body Clustering Probed by Dynamical Decoupling

URL: http://arxiv.org/abs/2504.15183v1
Date: Mon, 21 Apr 2025 15:46:05 GMT
Title: Multiple Quantum Many-Body Clustering Probed by Dynamical Decoupling
Authors: Gerónimo Sequeiros, Claudia M. Sánchez, Lisandro Buljubasich, Ana K. Chattah, Horacio M. Pastawski, Rodolfo H. Acosta,
Abstract summary: manipulation of quantum information in large systems requires precise control of quantum systems that are out-of-equilibrium.<n>We demonstrate that the system response during a prethermal period, subject to Floquet control, can be utilized to probe the multiple quantum evolution of dense and highly connected spin systems.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The manipulation of quantum information in large systems requires precise control of quantum systems that are out-of-equilibrium. As the size of the system increases, its fragility in response to external perturbations and intrinsic decoherence processes also increases. The degradation of the system response makes accurate measurements a challenging and time-consuming task. However, quantum information lifetime enhancement can be achieved by dynamical decoupling techniques (DD), where an external drive with a frequency much higher than the system's internal evolution renders signal acquisition with decay times greater than 1000-fold. In this study, we demonstrate that the system response during a prethermal period, subject to Floquet control, can be utilized to probe the multiple quantum evolution of dense and highly connected spin systems. This approach exhibits an enhanced sensitivity at a reduced experimental time. The enhanced signal-to-noise ratio achieved enabled the use of numerical inversion strategies to model the evolution of the excited multiple quantum coherences, which describe the number of correlated spins within a cluster. We observed for the first time, to the best of our knowledge, that the increase in the number of correlated spins with multiple quantum evolution is accompanied by an increase in the distribution of spin cluster sizes, which follows a quadratic law.

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