Predicting Open Quantum Dynamics with Data-Informed Quantum-Classical Dynamics

Pinchen Xie; Ke Wang; Anupam Mitra; Yuanran Zhu; Xiantao Li; Wibe Albert De Jong; Chao Yang

doi:10.1103/7lsx-ssjl

Predicting Open Quantum Dynamics with Data-Informed Quantum-Classical Dynamics

Pinchen Xie
, Ke Wang
, Anupam Mitra
, Yuanran Zhu
, Xiantao Li
, Wibe Albert De Jong
, Chao Yang

Research output: Contribution to journal › Article › peer-review

Abstract

We introduce a data-informed quantum-classical dynamics (DIQCD) approach for predicting the evolution of an open quantum system. The equation of motion in DIQCD is a Lindblad equation with a flexible, time-dependent Hamiltonian that can be optimized to fit sparse and noisy data from local observations of an extensive open quantum system. We demonstrate the accuracy and efficiency of DIQCD for both experimental and simulated quantum devices. We show that DIQCD can predict entanglement dynamics of ultracold molecules (calcium fluoride) in optical tweezer arrays. DIQCD also successfully predicts carrier mobility in organic semiconductors (rubrene) with accuracy comparable to nearly exact numerical methods.

Original language	English (US)
Article number	010402
Journal	Physical review letters
Volume	136
Issue number	1
DOIs	https://doi.org/10.1103/7lsx-ssjl
State	Published - Jan 9 2026

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/7lsx-ssjl

Cite this

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title = "Predicting Open Quantum Dynamics with Data-Informed Quantum-Classical Dynamics",

abstract = "We introduce a data-informed quantum-classical dynamics (DIQCD) approach for predicting the evolution of an open quantum system. The equation of motion in DIQCD is a Lindblad equation with a flexible, time-dependent Hamiltonian that can be optimized to fit sparse and noisy data from local observations of an extensive open quantum system. We demonstrate the accuracy and efficiency of DIQCD for both experimental and simulated quantum devices. We show that DIQCD can predict entanglement dynamics of ultracold molecules (calcium fluoride) in optical tweezer arrays. DIQCD also successfully predicts carrier mobility in organic semiconductors (rubrene) with accuracy comparable to nearly exact numerical methods.",

author = "Pinchen Xie and Ke Wang and Anupam Mitra and Yuanran Zhu and Xiantao Li and \{De Jong\}, \{Wibe Albert\} and Chao Yang",

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AU - Xie, Pinchen

AU - Wang, Ke

AU - Mitra, Anupam

AU - Zhu, Yuanran

AU - Li, Xiantao

AU - De Jong, Wibe Albert

AU - Yang, Chao

PY - 2026/1/9

Y1 - 2026/1/9

N2 - We introduce a data-informed quantum-classical dynamics (DIQCD) approach for predicting the evolution of an open quantum system. The equation of motion in DIQCD is a Lindblad equation with a flexible, time-dependent Hamiltonian that can be optimized to fit sparse and noisy data from local observations of an extensive open quantum system. We demonstrate the accuracy and efficiency of DIQCD for both experimental and simulated quantum devices. We show that DIQCD can predict entanglement dynamics of ultracold molecules (calcium fluoride) in optical tweezer arrays. DIQCD also successfully predicts carrier mobility in organic semiconductors (rubrene) with accuracy comparable to nearly exact numerical methods.

AB - We introduce a data-informed quantum-classical dynamics (DIQCD) approach for predicting the evolution of an open quantum system. The equation of motion in DIQCD is a Lindblad equation with a flexible, time-dependent Hamiltonian that can be optimized to fit sparse and noisy data from local observations of an extensive open quantum system. We demonstrate the accuracy and efficiency of DIQCD for both experimental and simulated quantum devices. We show that DIQCD can predict entanglement dynamics of ultracold molecules (calcium fluoride) in optical tweezer arrays. DIQCD also successfully predicts carrier mobility in organic semiconductors (rubrene) with accuracy comparable to nearly exact numerical methods.

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ER -

Predicting Open Quantum Dynamics with Data-Informed Quantum-Classical Dynamics

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All Science Journal Classification (ASJC) codes

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