Structure and Spectra of Three-Dimensional<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mo>(</mml:mo><mml:mrow><mml:msub><mml:mrow><mml:mi>H</mml:mi></mml:mrow><mml:mrow><mml:mn>2</mml:mn></mml:mrow></mml:msub></mml:mrow><mml:mi>O</mml:mi><mml:mrow><mml:msub><mml:mrow><mml:mo>)</mml:mo></mml:mrow><mml:mrow><mml:mi mathvariant="italic">n</mml:mi></mml:mrow></mml:msub></mml:mrow></mml:math>Clusters,<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml

Several stochastic simulations of the TIP4P ͓W. L. Jorgensen, J. Chandrasekhar, J. D. Madura, R. W. Impey, and M. L. Klein, J. Chem. Phys. 79, 926 ͑1983͔͒ water octamer are performed. Use is made of the stereographic projection path integral and the Green's function stereographic projection diffusion Monte Carlo techniques, recently developed in one of our groups. The importance sampling for the diffusion Monte Carlo algorithm is obtained by optimizing a simple wave function using variational Monte Carlo enhanced with parallel tempering to overcome quasiergodicity problems. The quantum heat capacity of the TIP4P octamer contains a pronounced melting peak at 160 K, about 50 K lower than the classical melting peak. The zero point energy of the TIP4P water octamer is 0.0348Ϯ 0.0002 hartree. By characterizing several large samples of configurations visited by both guided and unguided diffusion walks, we determine that both the TIP4P and the SPC ͓H. J. C. Berendsen, J. P. Postma, W. F. von Gunsteren, and J. Hermans, ͑Intermolecular Forces, Reidel, 1981͒. p. 331͔ octamer have a ground state wave functions predominantly contained within the D 2d basin of attraction. This result contrasts with the structure of the global minimum for the TIP4P potential, which is an S 4 cube. Comparisons of the thermodynamic and ground-state properties are made with the SPC octamer as well.

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The thermodynamic and ground state properties of the TIP4P water octamer

Asare

Musah

Curotto

et al. 2009

“…Many-body interactions in water have also been probed by molecular-beam spectroscopy: high-resolution far-infrared spectra were recorded for the water trimer, tetramer, pentamer, and hexamer, [18][19][20][21][22][23][24][25] mid-and near-infrared spectra for clusters up to the decamer. [26][27][28][29] The temperature of these clusters is usually around 5 K, which is so cold that only a few levels are thermally occupied. The observed lines in the high-resolution spectra correspond to transitions between the individual quantum levels of the clusters, with well-defined rotational quantum numbers J and K and with even minute tunneling splittings ͑less than 1 MHz͒ resolved.…”

Section: Introductionmentioning

confidence: 99%

Water pair potential of near spectroscopic accuracy. II. Vibration–rotation–tunneling levels of the water dimer

Groenenboom

Wormer

Avoird

et al. 2000

120

167

Nearly exact six-dimensional quantum calculations of the vibration-rotation-tunneling ͑VRT͒ levels of the water dimer for values of the rotational quantum numbers J and K р2 show that the SAPT-5s water pair potential presented in the preceding paper ͑paper I͒ gives a good representation of the experimental high-resolution far-infrared spectrum of the water dimer. After analyzing the sensitivity of the transition frequencies with respect to the linear parameters in the potential we could further improve this potential by using only one of the experimentally determined tunneling splittings of the ground state in (H 2 O) 2 . The accuracy of the resulting water pair potential, SAPT-5st, is established by comparison with the spectroscopic data of both (H 2 O) 2 and (D 2 O) 2 : ground and excited state tunneling splittings and rotational constants, as well as the frequencies of the intermolecular vibrations.

“…This is particularly the case for neutral clusters whose sizes are difficult to determine unambiguously. Although there have been several successful examples in this direction, [3][4][5] the range of exploration is expected to be severely limited by the lack of proper mass-selection means. For charged clusters, this limitation is apparently removed since they can be easily sizeselected by mass spectrometry.…”

mentioning

confidence: 99%

Identification of CH3OH2+ and H3O+-centered cluster isomers from fragment-dependent vibrational predissociation spectra of H+(CH3OH)4H2O

Chaudhuri

Jiang

Wang

et al. 2000

Cluster isomers of H ϩ ͑CH 3 OH͒ 4 H 2 O have been identified by vibrational predissociation spectroscopy in combination with mass-selected detection of photofragments. Ab initio calculations indicate that the cluster ion can exist in either CH 3 OH 2 ϩ ͑CH 3 OH͒ 3 H 2 O or H 3 O ϩ ͑CH 3 OH͒ 4 isomeric forms. They can dissociate via a methanol loss or water loss channel, depending on the structure of the isomers. While water loss is the dominant channel of the dissociation, the methanol loss channel is readily accessible by the H 3 O ϩ -centered cluster isomer. We demonstrate in this study that mass-selected detection of photofragments produced by vibrational excitation is an effective way of identifying cluster isomers in the gas phase. © 2000 American Institute of Physics. ͓S0021-9606͑00͒01917-6͔A central issue in the studies of atomic and molecular clusters has been the identification of structural isomers. Studies on this subject have been extensive in the past three decades, 1 leading to the discovery and suggestion of many interesting macromolecular structures. One noticeable example is the identification of the structure of carbon clusters by ion mobility measurements using a drift tube. Monocyclic as well as polycyclic rings have been suggested to be stable isomers of the C 60 ϩ cluster ion, 2 in addition to the spheroidal fullerenes. Unfortunately, up to now, detailed spectroscopic examination of these intriguing cluster isomers remains lacking. Identification of cluster isomers by spectroscopic means has been deemed a difficult task. This is particularly the case for neutral clusters whose sizes are difficult to determine unambiguously. Although there have been several successful examples in this direction, 3-5 the range of exploration is expected to be severely limited by the lack of proper mass-selection means. For charged clusters, this limitation is apparently removed since they can be easily sizeselected by mass spectrometry. We have recently reported on the observations of various cluster isomers of NH 4 ϩ ͑H 2 O͒ 2-7 , 6 H ϩ ͑CH 3 OH͒ 4,5 , 7 H ϩ ͓͑CH 3 ͒ 2 O͔͒ 2 ͑H 2 O͒, 8 and H ϩ ͑CH 3 OH͒͑H 2 O͒ 1-6 ͑Ref. 9͒ using vibrational predissociation spectroscopy. Identification of the isomers was accomplished by varying cluster temperature over a range of Ϯ20 K and observing the corresponding peak intensity changes with the temperature. Here, we report a new and alternative means of identifying cluster isomers and demonstrate the feasibility of this approach, which involves mass-selected detection of photofragments, using the mixed methanolwater cluster ions H ϩ ͑CH 3 OH͒ 4 H 2 O as a benchmark system. A mixed methanol-water cluster ion ͓H ϩ ͑CH 3 OH͒ m (H 2 O) n ͔ can exist in a variety of isomeric forms. Interestingly, they can be either centered with CH 3 OH 2 ϩ or with H 3 O ϩ , depending on the structure and size of the cluster. Previous experiments 9-12 and calculations 9 have shown that these two isomeric forms ͑CH 3 OH 2 ϩ and H 3 O ϩ -centered͒ are comparable in stability when the cluster is...