The structure of the Calix[4]arene-(H2O) cluster, world’s smallest cup of water
Journal of Physical Chemistry A Volume 114 Issue 9
Page 2967-2972
published_at 2010-03-11
アクセス数 : 822 件
ダウンロード数 : 187 件
今月のアクセス数 : 0 件
今月のダウンロード数 : 1 件
この文献の参照には次のURLをご利用ください : https://ir.lib.hiroshima-u.ac.jp/00038061
| File | |
| Title ( eng ) |
The structure of the Calix[4]arene-(H2O) cluster, world’s smallest cup of water
|
| Creator |
Hontama Naoya
Dedonder-Lardeux Claude
Jouvet Christophe
Xantheas Sotiris S.
|
| Source Title |
Journal of Physical Chemistry A
|
| Volume | 114 |
| Issue | 9 |
| Start Page | 2967 |
| End Page | 2972 |
| Abstract |
The structure of the calix[4]arene(C4A)-(H2O) cluster formed in a supersonic beam has been investigated by mass-selected resonant two-photon ionization (R2PI) spectroscopy, IR-UV double resonance spectroscopy, IR photodissociation (IRPD) spectroscopy and by high level quantum chemical calculations. The IR-UV double resonance spectrum of C4A-(H2O) exhibits a broad and strong hydrogen-bonded OH stretching band at 3160 cm-1 and a weak asymmetric OH stretching band at 3700 cm-1. The IRPD measurement of the cluster produced a value of 3140 cm-1 for the C4A-(H2O) → C4A + H2O dissociation energy. High level electronic structure calculations at the MP2 level of theory with basis sets up to quadruple zeta quality suggest that the endo-isomer (water inside the C4A cavity) is ~1100 cm-1 more stable than the exo-isomer (water hydrogen bonded to the rim of C4A). The endo-isomer has a best-computed (at the MP2/aug-cc-pVQZ level) value of 3127 cm-1 for the binding energy, just ~15 cm-1 shy of the experimentally determined threshold and an IR spectrum in excellent agreement with the experimentally observed one. In contrast, the B3LYP density functional fails to even predict a stable structure for the endo-isomer demonstrating the inability of that level of theory to describe the delicate balance between structures exhibiting cumulative OH-π H-bonding and dipole-dipole interactions (endo-isomer) when compared to the ones emanating from maximizing the cooperative effects associated with the formation of hydrogen bonded homodromic networks (exo-isomer). The comparison of the experimental results with the ones from high level electronic structure calculations therefore unambiguously assign the endo-isomer as the global minimum of the C4A-(H2O) cluster, world’s smallest cup of water.
|
| Descriptions |
This is a preprint of an article published by American Chemical Society in Journal of Physical Chemistry A, 2010, available online: http://pubs.acs.org/doi/abs/10.1021/jp902967q
|
| NDC |
Chemistry [ 430 ]
|
| Language |
eng
|
| Resource Type | journal article |
| Publisher |
American Chemical Society
|
| Date of Issued | 2010-03-11 |
| Rights |
Copyright (c) 2009 American Chemical Society
|
| Publish Type | Author’s Original |
| Access Rights | open access |
| Source Identifier |
[ISSN] 1089-5639
[DOI] 10.1021/jp902967q
[DOI] http://dx.doi.org/10.1021/jp902967q
isVersionOf
|
