posted on 2024-11-14, 13:08authored byHao Zeng, Yitian Kou, Xiang Sun
Nonadiabatic dynamics is key for understanding solar
energy conversion
and photochemical processes in condensed phases. This often involves
the non-Markovian dynamics of the reduced density matrix in open quantum
systems, where knowledge of the system’s prior states is necessary
to predict its future behavior. In this study, we explore time-series
machine learning methods for predicting long-time nonadiabatic dynamics
based on short-time input data, comparing these methods with the physics-based
transfer tensor method (TTM). To understand the impact of memory time
on these approaches, we demonstrate that non-Markovian dynamics can
be represented as a linear map within the Nakajima-Zwanzig generalized
quantum master equation framework. We further propose a practical
method to estimate the effective memory time, within a given tolerance,
for reduced density matrix propagation. Our predictive models are
applied to various physical systems, including spin-boson models,
multistate harmonic (MSH) models with Ohmic spectral densities and
for a realistic organic photovoltaic system composed of a carotenoid-porphyrin-fullerene
triad dissolved in tetrahydrofuran. Results indicate that the simple
linear-mapping fully connected neural network (FCN) outperforms the
more complicated nonlinear-mapping networks including the gated recurrent
unit (GRU) and the convolutional neural network/long short-term memory
(CNN-LSTM) in systems with short memory times, such as spin-boson
and MSH models. Conversely, the nonlinear CNN-LSTM and GRU models
yield higher accuracy in the triad MSH systems characterized by long
memory times. These findings offer valuable insights into the role
of effective memory time in non-Markovian quantum dynamics, providing
practical guidance for the application of time-series machine learning
models to complex chemical systems.