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Autori principali: Qin, Yangjun, Mu, Liuhua, Wan, Xiao, Zong, Zhicheng, Li, Tianhao, Yang, Nuo
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2408.15797
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author Qin, Yangjun
Mu, Liuhua
Wan, Xiao
Zong, Zhicheng
Li, Tianhao
Yang, Nuo
author_facet Qin, Yangjun
Mu, Liuhua
Wan, Xiao
Zong, Zhicheng
Li, Tianhao
Yang, Nuo
contents The influence of hydrated cation-π interaction forces on the adsorption and filtration capabilities of graphene-based membrane materials is significant. However, the lack of interaction potential between hydrated Cs+ and graphene limits the scope of adsorption studies. Here, it is developed that a deep neural network potential function model to predict the interaction force between hydrated Cs+ and graphene. The deep potential has DFT-level accuracy, enabling accurate property prediction. This deep potential is employed to investigate the properties of the graphene surface solution, including the density distribution, mean square displacement, and vibrational power spectrum of water. Furthermore, calculations of the molecular orbital electron distributions indicate the presence of electron migration in the molecular orbitals of graphene and hydrated Cs+, resulting in a strong electrostatic interaction force. The method provides a powerful tool to study the adsorption behavior of hydrated cations on graphene surfaces and offers a new solution for handling radionuclides.
format Preprint
id arxiv_https___arxiv_org_abs_2408_15797
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Deep potential for interaction between hydrated Cs+ and graphene
Qin, Yangjun
Mu, Liuhua
Wan, Xiao
Zong, Zhicheng
Li, Tianhao
Yang, Nuo
Computational Physics
The influence of hydrated cation-π interaction forces on the adsorption and filtration capabilities of graphene-based membrane materials is significant. However, the lack of interaction potential between hydrated Cs+ and graphene limits the scope of adsorption studies. Here, it is developed that a deep neural network potential function model to predict the interaction force between hydrated Cs+ and graphene. The deep potential has DFT-level accuracy, enabling accurate property prediction. This deep potential is employed to investigate the properties of the graphene surface solution, including the density distribution, mean square displacement, and vibrational power spectrum of water. Furthermore, calculations of the molecular orbital electron distributions indicate the presence of electron migration in the molecular orbitals of graphene and hydrated Cs+, resulting in a strong electrostatic interaction force. The method provides a powerful tool to study the adsorption behavior of hydrated cations on graphene surfaces and offers a new solution for handling radionuclides.
title Deep potential for interaction between hydrated Cs+ and graphene
topic Computational Physics
url https://arxiv.org/abs/2408.15797