机构地区:[1]Henan Key Laboratory of Biomolecular Recognition and Sensing,Henan Joint International Research Laboratory of Chemo/Biosensing and Early Diagnosis of Major Diseases,College of Chemistry and Chemical Engineering,Shangqiu Normal University,Shangqiu 476000,China [2]State Key Laboratory of Physical Chemistry of Solid Surfaces,iChEM,College of Chemistry and Chemical Engineering,Xiamen University,Xiamen 361005,China [3]Chaire de Simulation àl’Échelle Atomique(CSEA),Ecole Polytechnique Fédérale de Lausanne(EPFL),CH-1015 Lausanne,Switzerland [4]Department of Chemistry-Agstrom Laboratory,Uppsala University,75121 Uppsala,Sweden [5]Laboratory of AI for Electrochemistry(AI4EC),IKKEM,Xiamen 361005,China [6]Institute of Artificial Intelligence,Xiamen University,Xiamen 361005,China
出 处:《Precision Chemistry》2024年第12期644-654,共11页精准化学(英文)
基 金:funding from the National Science Fund for Distinguished Young Scholars(Grant No.22225302);the National Natural Science Foundation of China(Grant Nos.92161113,21991151,21991150,and 22021001);the Fundamental Research Funds for the Central Universities(Grant Nos.20720220008,20720220009,20720220010);Laboratory of AI for Electrochemistry(AI4EC);IKKEM(Grant Nos.RD2023100101 and RD2022070501);M.J.greatly appreciates the financial support from the Natural Science Foundation of Henan Province(Grant No.242300420420570);the Key Scientific Research Projects of Colleges and Universities in Henan Province(No.24A150031);the International Scientific and Technological Cooperation Projects in Henan Province(No.232102520020)。
摘 要:The interfacial proton transfer(PT)reaction on the metal oxide surface is an important step in many chemical processes including photoelectrocatalytic water splitting,dehydrogenation,and hydrogen storage.The investigation of the PT process,in terms of thermodynamics and kinetics,has received considerable attention,but the individual free energy barriers and solvent effects for different PT pathways on rutile oxide are still lacking.Here,by applying a combination of ab initio and deep potential molecular dynamics methods,we have studied interfacial PT mechanisms by selecting the rutile SnO_(2)(110)/H_(2)O interface as an example of an oxide with the characteristic of frequently interfacial PT processes.Three types of PT pathways among the interfacial groups are found,i.e.,proton transfer from terminal adsorbed water to bridge oxygen directly(surface-PT)or via a solvent water(mediated-PT),and proton hopping between two terminal groups(adlayer PT).Our simulations reveal that the terminal water in mediated-PT prefers to point toward the solution and forms a shorter H-bond with the assisted solvent water,leading to the lowest energy barrier and the fastest relative PT rate.In particular,it is found that the full solvation environment plays a crucial role in water-mediated proton conduction,while having little effect on direct PT reactions.The PT mechanisms on aqueous rutile oxide interfaces are also discussed by comparing an oxide series composed of SnO_(2),TiO_(2),and IrO_(2).Consequently,this work provides valuable insights into the ability of a deep neural network to reproduce the ab initio potential energy surface,as well as the PT mechanisms at such oxide/liquid interfaces,which can help understand the important chemical processes in electrochemistry,photoelectrocatalysis,colloid science,and geochemistry.
关 键 词:Proton transfer mechanism ab initio molecular dynamics deep potential molecular dynamics rutile oxide machine learning solvation effect free energy
分 类 号:O57[理学—粒子物理与原子核物理]
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