1972
DOI: 10.1021/ja00777a003
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Kinetic study of the proton hydrate H+(H2O)n equilibriums in the gas phase

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1973
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Cited by 257 publications
(174 citation statements)
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“…This shell filling effect has been observed in the earliest experiment of Kebarle and co-workers. 15 In Table 1, we also include the results of OH -(H 2 O) 3-7 for comparison with literature values. The listed internal energies of OH -(H 2 O) [3][4][5][6] are averages of the 〈E vib 〉 of DFT-predicted low-energy isomers.…”
Section: Resultsmentioning
confidence: 99%
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“…This shell filling effect has been observed in the earliest experiment of Kebarle and co-workers. 15 In Table 1, we also include the results of OH -(H 2 O) 3-7 for comparison with literature values. The listed internal energies of OH -(H 2 O) [3][4][5][6] are averages of the 〈E vib 〉 of DFT-predicted low-energy isomers.…”
Section: Resultsmentioning
confidence: 99%
“…12 The importance of the latter surely stems from the high abundance of water on earth and the ease of charge separation of the water molecule within clusters, 13 as H 2 O has a high proton affinity of 165 kcal mol -1 and basicity of 157 kcal mol -1 in the gas phase. 14 Experiments with the water cluster ions [H + (H 2 O) n ] go back to the 1970s when the Kebarle group 15 first investigated these ions in a pulsed high-pressure mass spectrometer and deduced the cluster bond energies and other thermochemical quantities from the temperature dependence of equilibrium constants. After emergence of the corona discharge source 3 for production of internally cold clusters, detailed spectroscopic investigations followed, [16][17][18] revealing important structural information for cluster ions of a size up to n ) 8.…”
Section: Introductionmentioning
confidence: 99%
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“…The free energy change per addition of a single ligand (ΔG n,n-1 ) may be approximated by differentiating the negative of eq 2 with respect to size, n ,53 resulting in (SI units) (5) where the first term is the bulk free energy of vaporization (ΔG vap ), and P 0 is the vapor pressure of L at temperature T. Stepwise binding entropies (ΔS n,n-1 ) are calculated by differentiating eq 5 with respect to temperature (ΔS = −∂ΔG/∂T) holding the internal droplet pressure constant. The approximate sequential binding enthalpies (ΔH n,n-1 ) were obtained from the thermodynamic relationship (6) Results of the C model using physical properties of water at 313 K (Table 1) are shown in Figure 1 for monovalent, divalent, and trivalent ions as a function of cluster size. As expected, higher charge states result in significantly higher calculated ΔH n,n-1 values, and this effect is most pronounced at smaller cluster sizes.…”
Section: Continuous Thomson Modelmentioning
confidence: 99%
“…In ion nanocalorimetry, a measure of the internal energy that is deposited into a cluster upon activation is obtained from the distribution of ligands that are lost from the cluster. For example, electron capture by [Ru(NH 3 ) 6 (H 2 O) 55 ] 3+ results in the loss of 17-19 water molecules from the reduced precursor. 48,49 For large clusters such as this, the recombination energy is determined predominantly from the sum of the ligand binding energies for each water molecule lost.…”
Section: Introductionmentioning
confidence: 99%