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Ab Initio Molecular Dynamics Studies of the Electric-Field-Induced Catalytic Effects on Liquids
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SYSNO ASEP 0555436 Document Type J - Journal Article R&D Document Type Journal Article Subsidiary J Článek ve WOS Title Ab Initio Molecular Dynamics Studies of the Electric-Field-Induced Catalytic Effects on Liquids Author(s) Cassone, G. (IT)
Šponer, Jiří (BFU-R) RID, ORCID
Saija, F. (IT)Number of authors 3 Source Title Topics in Catalysis. - : Springer - ISSN 1022-5528
Roč. 65, č. 1-4 (2022), s. 40-58Number of pages 19 s. Publication form Print - P Language eng - English Country NL - Netherlands Keywords aqueous-solutions ; proton-transfer ; prebiotic synthesis ; functional theory ; ionic-diffusion ; water ices OECD category Physical chemistry Method of publishing Limited access Institutional support BFU-R - RVO:68081707 UT WOS 000682412300001 EID SCOPUS 85112620055 DOI https://doi.org/10.1007/s11244-021-01487-0 Annotation Electric fields produce a range of effects by interacting with atoms, molecules, and complex matter modifying the activation barriers of chemical reactions, shaping their free-energy landscapes and reaction pathways, and hence holding a crucial place in catalysis. Owing to the development of novel theories and advanced computational approaches, nowadays supercomputing resources are routinely exploited to investigate the catalytic effects observed when intense electric fields are applied on condensed matter. Within this context, ab initio molecular dynamics simulations coupled with free-energy methods represent unique computational tools allowing for the fine characterization of the role played by static electric fields in activating chemical processes in liquids. Furthermore, the achievement of including crucial nuclear quantum effects in path-integral ab initio molecular dynamics simulations paves the way toward the systematic investigation of the field-induced catalytic effects on matter treated as a fully quantum object. In this review, a series of recent findings on the catalytic effects produced by applying strong electric fields on liquids, with implications not only in technological and industrial realms but also in investigating the origins of life enigma, are reported. Workplace Institute of Biophysics Contact Jana Poláková, polakova@ibp.cz, Tel.: 541 517 244 Year of Publishing 2022 Electronic address https://link.springer.com/article/10.1007/s11244-021-01487-0
Number of the records: 1