Accelerating Computation
of Acidity Constants and
Redox Potentials for Aqueous Organic Redox Flow Batteries by Machine
Learning Potential-Based Molecular Dynamics
Due to the increased concern about energy and environmental
issues,
significant attention has been paid to the development of large-scale
energy storage devices to facilitate the utilization of clean energy
sources. The redox flow battery (RFB) is one of the most promising
systems. Recently, the high cost of transition-metal complex-based
RFB has promoted the development of aqueous RFBs with redox-active
organic molecules. To expand the working voltage, computational chemistry
has been applied to search for organic molecules with lower or higher
redox potentials. However, redox potential computation based on implicit
solvation models would be challenging due to difficulty in parametrization
when considering the complex solvation of supporting electrolytes.
Besides, although ab initio molecular dynamics (AIMD) describes the
supporting electrolytes with the same level of electronic structure
theory as the redox couple, the application is impeded by the high
computation costs. Recently, machine learning molecular dynamics (MLMD)
has been illustrated to accelerate AIMD by several orders of magnitude
without sacrificing the accuracy. It has been established that redox
potentials can be computed by MLMD with two separated machine learning
potentials (MLPs) for reactant and product states, which is redundant
and inefficient. In this work, an automated workflow is developed
to construct a universal MLP for both states, which can compute the
redox potentials or acidity constants of redox-active organic molecules
more efficiently. Furthermore, the predicted redox potentials can
be evaluated at the hybrid functional level with much lower costs,
which would facilitate the design of aqueous organic RFBs