Response of the hydrogen bond network to the ionization of bulk water: Ab initio molecular dynamic simulations using H2S(aq)

Liang Chun Lin; Jer Ming Liang; En Ping Lu; Ming Kang Tsai

doi:10.1016/j.cplett.2015.04.034

Response of the hydrogen bond network to the ionization of bulk water: Ab initio molecular dynamic simulations using H₂S(aq)

Liang Chun Lin, Jer Ming Liang, En Ping Lu, Ming Kang Tsai^*

^*此作品的通信作者

化學系

研究成果: 雜誌貢獻 › 期刊論文 › 同行評審

2 引文斯高帕斯（Scopus）

摘要

Abstract The H₂S⁺ ligand was used to study the first proton-transfer (PT1) process in microsolvation and aqueous environments. The average time scale of PT1 of (H₂O)₃⁺ clusters (Δt_PT1 = 22.8 fs) was notably shorter than that of (H₂O)₂H₂S⁺ clusters at 79.5 fs. Compared with cationic-water clusters, the smaller potential energy gain observed in the H₂S-containing clusters was considered the dominant factor for such slow PT1 dynamics. Δt_PT1 of the [H₂S]⁺(aq) at 106.5 fs was significantly longer than the (H₂O)₂H₂S⁺ clusters. The stabilization effect resulting from the solvent reorientation and formation of H₂S⁺⋯¯OH₂ hemibond interactions was responsible for this delay.

原文	英語
文章編號	32942
頁（從 - 到）	62-67
頁數	6
期刊	Chemical Physics Letters
卷	630
DOIs	https://doi.org/10.1016/j.cplett.2015.04.034
出版狀態	已發佈 - 2015 6月 1

ASJC Scopus subject areas

物理與天文學 (全部)
物理與理論化學

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10.1016/j.cplett.2015.04.034

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title = "Response of the hydrogen bond network to the ionization of bulk water: Ab initio molecular dynamic simulations using H2S(aq)",

abstract = "Abstract The H2S+ ligand was used to study the first proton-transfer (PT1) process in microsolvation and aqueous environments. The average time scale of PT1 of (H2O)3+ clusters (ΔtPT1 = 22.8 fs) was notably shorter than that of (H2O)2H2S+ clusters at 79.5 fs. Compared with cationic-water clusters, the smaller potential energy gain observed in the H2S-containing clusters was considered the dominant factor for such slow PT1 dynamics. ΔtPT1 of the [H2S]+(aq) at 106.5 fs was significantly longer than the (H2O)2H2S+ clusters. The stabilization effect resulting from the solvent reorientation and formation of H2S+⋯¯OH2 hemibond interactions was responsible for this delay.",

author = "Lin, {Liang Chun} and Liang, {Jer Ming} and Lu, {En Ping} and Tsai, {Ming Kang}",

note = "Funding Information: The authors are grateful for the financial support from Ministry of Science and Technology of Taiwan (Grant 101-2113-M-003-003-MY2 ). We would like to thank Prof. Jer-Lai Kuo for the helpful discussions. Computational resources are supported by the National Center for High Performance Computing in Taiwan. Publisher Copyright: {\textcopyright} 2015 Elsevier B.V. All rights reserved.",

year = "2015",

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doi = "10.1016/j.cplett.2015.04.034",

language = "English",

volume = "630",

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T2 - Ab initio molecular dynamic simulations using H2S(aq)

AU - Lin, Liang Chun

AU - Liang, Jer Ming

AU - Lu, En Ping

AU - Tsai, Ming Kang

N1 - Funding Information: The authors are grateful for the financial support from Ministry of Science and Technology of Taiwan (Grant 101-2113-M-003-003-MY2 ). We would like to thank Prof. Jer-Lai Kuo for the helpful discussions. Computational resources are supported by the National Center for High Performance Computing in Taiwan. Publisher Copyright: © 2015 Elsevier B.V. All rights reserved.

PY - 2015/6/1

Y1 - 2015/6/1

N2 - Abstract The H2S+ ligand was used to study the first proton-transfer (PT1) process in microsolvation and aqueous environments. The average time scale of PT1 of (H2O)3+ clusters (ΔtPT1 = 22.8 fs) was notably shorter than that of (H2O)2H2S+ clusters at 79.5 fs. Compared with cationic-water clusters, the smaller potential energy gain observed in the H2S-containing clusters was considered the dominant factor for such slow PT1 dynamics. ΔtPT1 of the [H2S]+(aq) at 106.5 fs was significantly longer than the (H2O)2H2S+ clusters. The stabilization effect resulting from the solvent reorientation and formation of H2S+⋯¯OH2 hemibond interactions was responsible for this delay.

AB - Abstract The H2S+ ligand was used to study the first proton-transfer (PT1) process in microsolvation and aqueous environments. The average time scale of PT1 of (H2O)3+ clusters (ΔtPT1 = 22.8 fs) was notably shorter than that of (H2O)2H2S+ clusters at 79.5 fs. Compared with cationic-water clusters, the smaller potential energy gain observed in the H2S-containing clusters was considered the dominant factor for such slow PT1 dynamics. ΔtPT1 of the [H2S]+(aq) at 106.5 fs was significantly longer than the (H2O)2H2S+ clusters. The stabilization effect resulting from the solvent reorientation and formation of H2S+⋯¯OH2 hemibond interactions was responsible for this delay.

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Response of the hydrogen bond network to the ionization of bulk water: Ab initio molecular dynamic simulations using H2S(aq)

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Response of the hydrogen bond network to the ionization of bulk water: Ab initio molecular dynamic simulations using H₂S(aq)