Related papers: Time series learning in a many-body Rydberg system with emergent collective nonlinearity

Time series learning in a many-body Rydberg system with emergent collective nonlinearity

URL: http://arxiv.org/abs/2511.15047v1
Date: Wed, 19 Nov 2025 02:38:04 GMT
Title: Time series learning in a many-body Rydberg system with emergent collective nonlinearity
Authors: Zongkai Liu, Qiming Ren, Chris Nill, Albert Cabot, Wei Xia, Yanjie Tong, Huizhen Wang, Wenguang Yang, Junyao Xie, Mingyong Jing, Hao Zhang, Liantuan Xiao, Suotang Jia, Igor Lesanovsky, Linjie Zhang,
Abstract summary: Close to a non-equilibrium phase transition, Rydberg atoms respond collectively to external perturbations.<n>We investigate the application of an interacting Rydberg vapour for the purpose of time series prediction.<n>We find that close to a non-equilibrium phase transition, where collective effects are amplified, the capability of the system to learn the input becomes enhanced.
Score: 9.378995397505749
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Interacting Rydberg atoms constitute a versatile platform for the realization of non-equilibrium states of matter. Close to phase transitions, they respond collectively to external perturbations, which can be harnessed for technological applications in the domain of quantum metrology and sensing. Owing to the controllable complexity and straightforward interpretability of Rydberg atoms, we can observe and tune the emergent collective nonlinearity. Here, we investigate the application of an interacting Rydberg vapour for the purpose of time series prediction. The vapour is driven by a laser field whose Rabi frequency is modulated in order to input the time series. We find that close to a non-equilibrium phase transition, where collective effects are amplified, the capability of the system to learn the input becomes enhanced. This is reflected in an increase of the accuracy with which future values of the time series can be predicted. Using the Lorenz time series and temperature data as examples, our work demonstrates how emergent phenomena enhance the capability of noisy many-body quantum systems for data processing and forecasting.

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