Structures and stability of hydrated clusters of hydrogen chloride, HCl(H2O)n, n=1–5

Re, Suyong; Osamura, Yoshihiro; Suzuki, Y; Schaefer, Henry F.

doi:10.1063/1.476640

Cited by 182 publications

(209 citation statements)

References 23 publications

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“…18 Re et al found that proton transfer in the hydrogen-bonded cluster HCl(H 2 O) n with n ) 1-5 completely occurs only in the case of n ) 5 clusters. 19 Using the B3LYP density functional method and the CCSD(T) ab initio method, Milet et al showed however that HCl starts dissociating already in HCl(H 2 O) 4 . 20 Devlin et al, using ab initio Monte Carlo simulations found that in HCl-(H 2 O) 6 three-coordinated HCl dissociates directly to form a clearly recognizable solvated Cl -and H 3 O + ion pair.…”

Section: Introductionmentioning

confidence: 99%

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters

et al. 2007

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Theoretical studies of the interaction of HCl with small water clusters have so far neglected the effect of temperature, which ranges from a few tens of kelvin in cluster experiments, up to about 250 K in typical atmospheric conditions. We study the dynamical behavior of a selected set of HCl(H 2 O) 6 clusters, representative of undissociated and dissociated configurations, by means of DFT-based first principles molecular dynamics. We find that the thermodynamcal stability of different configurations can be affected by temperature. We also present the infrared spectra of dissociated and undissociated configurations at 200 K and discuss the origin of the spectral features.

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Section: Introductionmentioning

confidence: 99%

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters

et al. 2007

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“…HCl(H 2 O) n and (H 2 O) n+1 clusters have similar structure and hydrogen bond strengths up to at least n = 3, after which dissociation of the acid into the ion pair is predicted to occur for the acid clusters 3,7 . The similar structures and hydrogen bond strengths of the acid and pure water clusters gives rise to similar vibrational modes.…”

Section: Resultsmentioning

confidence: 99%

“…At the MP2/6-31g(2dp) level the HCl bond length increases from the isolated molecule by 1.3% upon forming the dimer, 2.5 % for the two water cluster and 4.1% for the three water cluster . By the addition of a fourth water, the dissociated ion pair becomes the most stable product according to theory 3,7 .…”

Section: Resultsmentioning

confidence: 99%

Characterization of gas-phase HCl-H 2 O clusters using pulsed infrared cavity ringdown spectroscopy

Huneycutt

Stickland

Hellberg³

et al. 2002

SPIE Proceedings

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Using the Berkeley medium-resolution pulsed cavity ringdown spectrometer we have observed the HCl stretch spectrum of the HCl-H2O dimer and DCl stretch mode of the completely deuterated analog. The shifts from the free HCl stretch are consistent with theory and Ar matrix isolation work. Rotational structure was obtained for the deuterated cluster and spectroscopic constants for both chlorine isotopomers determined. Cluster number densities were determined to be slightly lower than found for the pure water dimer under similar conditions.

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“…One inquiry that persistently threads its way through this subject is: what is the minimum quantity of water molecules, (H 2 O) n , required to dissociate the acid [18]? According to calculations, the acidically dissociated structure is supported starting from n=4; most of the theoretical approaches agree that at this size the dissociated form represents the global minimum on the potential energy surface [18][19][20][21][22][23][24]. Experimentally, for neutral clusters the question has been probed by laser spectroscopy (see, e.g., [25][26][27][28]) but finding a conclusive spectroscopic signature of the onset of dissociation in a nanocluster is not straightforward.…”

Section: Introductionmentioning

confidence: 99%

Electric Dipole Moments of Nanosolvated Acid Molecules in Water Clusters

2015

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The electric dipole moments of (H 2 O) n DCl (n=3-9) clusters have been measured by the beam deflection method. Reflecting the (dynamical) charge distribution within the system, the dipole moment contributes information about the microscopic structure of nanoscale solvation.The addition of a DCl molecule to a water cluster results in a strongly enhanced susceptibility.There is evidence for a noticeable rise in the dipole moment occurring at n≈5-6. This size is consistent with predictions for the onset of ionic dissociation. Additionally, a molecular dynamics model suggests that even with a nominally bound impurity an enhanced dipole moment can arise due to the thermal and zero point motion of the proton and the water molecules. The experimental measurements and the calculations draw attention to the importance of fluctuations in defining the polarity of water-based nanoclusters, and generally to the essential role played by motional effects in determining the response of fluxional nanoscale systems under realistic conditions. 2 INTRODUCTION.Water clusters are convenient experimental platforms for the study of the microscopic physics and chemistry of solvation. By monitoring cluster properties as a function of the number of water molecules, it is possible to follow the step-by-step progression of intermolecular interactions [1], following the transition from isolated molecule to bulk By virtue of having a large fraction of their molecules located near the surface, clusters can serve as surrogates for important processes occurring on aerosols and hydrometeors [2,3]. Composed of only a finite number of constituents, they often serve as test beds for theoretical methods and models.Small water clusters doped with an acid molecule -here, for concreteness, hydrogen chloride -have been the subject of a great number of theoretical papers and a sizeable (but regrettably much smaller) number of experimental ones. Hydrogen chloride readily dissociates into H 3 O + and Cl -and the dissociation also takes place in HCl hydrates [4][5][6][7][8], on the ice surface [9][10][11][12] or on larger water nanoparticles [13][14][15] and protonated water cluster ions [16,17]. One inquiry that persistently threads its way through this subject is: what is the minimum quantity of water molecules, (H 2 O) n , required to dissociate the acid [18]? According to calculations, the acidically dissociated structure is supported starting from n=4; most of the theoretical approaches agree that at this size the dissociated form represents the global minimum on the potential energy surface [18][19][20][21][22][23][24]. Experimentally, for neutral clusters the question has been probed by laser spectroscopy (see, e.g., [25][26][27][28]) but finding a conclusive spectroscopic signature of the onset of dissociation in a nanocluster is not straightforward.As a matter of fact, the challenge is not just experimental but conceptual. The free water clusters in natural and laboratory environments generally exist at temperatures appreciably above absolute zero ...

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Structures and stability of hydrated clusters of hydrogen chloride, HCl(H2O)n, n=1–5

Cited by 182 publications

References 23 publications

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters

Characterization of gas-phase HCl-H 2 O clusters using pulsed infrared cavity ringdown spectroscopy

Electric Dipole Moments of Nanosolvated Acid Molecules in Water Clusters

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Structures and stability of hydrated clusters of hydrogen chloride, HCl(H2O)n, n=1–5

Cited by 182 publications

References 23 publications

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H2O)6 Clusters

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H2O)6 Clusters

Characterization of gas-phase HCl-H 2 O clusters using pulsed infrared cavity ringdown spectroscopy

Electric Dipole Moments of Nanosolvated Acid Molecules in Water Clusters

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Product

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Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters

Finite-Temperature Effects on the Stability and Infrared Spectra of HCl(H₂O)₆ Clusters