TY - JOUR
T1 - Response of the hydrogen bond network to the ionization of bulk water
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 - 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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U2 - 10.1016/j.cplett.2015.04.034
DO - 10.1016/j.cplett.2015.04.034
M3 - Article
AN - SCOPUS:84929092200
SN - 0009-2614
VL - 630
SP - 62
EP - 67
JO - Chemical Physics Letters
JF - Chemical Physics Letters
M1 - 32942
ER -