Mass-zero constrained molecular dynamics for electrode charges in simulations of electrochemical systems

Classical molecular dynamics simulations have recently become a standard tool for the study of electrochemical systems. State-of-the-art approaches represent the electrodes as perfect conductors, modeling their responses to the charge distribution of electrolytes via the so-called fluctuating charge...

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Bibliographic Details
Published in:The Journal of chemical physics 2020-05, Vol.152 (19), p.194701-194701
Main Authors: Coretti, A., Scalfi, L., Bacon, C., Rotenberg, B., Vuilleumier, R., Ciccotti, G., Salanne, M., Bonella, S.
Format: Article
Language:English
Subjects:
Charge distribution
Chemical Sciences
Computer simulation
Conductors
Degrees of freedom
Electrodes
Electrolytes
Evolutionary algorithms
Model accuracy
Molecular dynamics
Physics
State-of-the-art reviews
Water
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Summary:Classical molecular dynamics simulations have recently become a standard tool for the study of electrochemical systems. State-of-the-art approaches represent the electrodes as perfect conductors, modeling their responses to the charge distribution of electrolytes via the so-called fluctuating charge model. These fluctuating charges are additional degrees of freedom that, in a Born–Oppenheimer spirit, adapt instantaneously to changes in the environment to keep each electrode at a constant potential. Here, we show that this model can be treated in the framework of constrained molecular dynamics, leading to a symplectic and time-reversible algorithm for the evolution of all the degrees of freedom of the system. The computational cost and the accuracy of the new method are similar to current alternative implementations of the model. The advantage lies in the accuracy and long term stability guaranteed by the formal properties of the algorithm and in the possibility to systematically introduce additional kinematic conditions of arbitrary number and form. We illustrate the performance of the constrained dynamics approach by enforcing the electroneutrality of the electrodes in a simple capacitor consisting of two graphite electrodes separated by a slab of liquid water.
ISSN:0021-9606
1089-7690
DOI:10.1063/5.0007192