Microwave spectrum, structure, and dipole moment of sulfuric acid

Kuczkowski, Robert L.; Suenram, R. D.; Lovas, F. J.

doi:10.1021/ja00400a013

Cited by 144 publications

(115 citation statements)

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“…59 Studies imply there must be rather complicated reaction schemes in order to account for the hydrogen transfer mechanisms between molecules/ions in these small clusters. 60 61 (where all sulfur-oxygen bonds are tetrahedrally coordinated around the sulfur) is used as a starting point for the SO 4 -2 geometry (see Figure 1 for details of the SO 4 2δ-structure). The sulfur atom in the sulfuric acid molecule is said to be "hypervalent", thus, allowing the sulfur atom to maintain two S-O single bonds and two SdO double bonds.…”

Section: H 2 So 4 -H 2 O Potential Modelmentioning

confidence: 99%

Monte Carlo Simulations of Small Sulfuric Acid−Water Clusters

Kathmann

Hale

2001

J. Phys. Chem. B

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Effective atom-atom potentials are developed for binary sulfuric acid-water clusters and applied in a Bennett Metropolis Monte Carlo calculation to determine free energy differences for small neighboring sized clusters of fixed composition at 298 K. The atom-atom pair potentials consist of Lennard-Jones short-range and Coulombic long-range terms and assume rigid SO 4 2δ-with two unconstrained H δ+ and rigid H 2 O molecules interacting via revised central force (RSL2) potentials. The potential parameters are determined from both ab initio studies and tests of the potential using the statistical mechanical formalism for binary cluster size distributions. In the potential tests, fixed composition free energy differences, δf km,m , for [H 2 O] km [H 2 SO 4 ] m clusters are plotted versus (km + m) -1/3 , and the resulting slope and intercept (in the large cluster regime) are used to extract model dependent binary liquid surface tension and partial vapor pressures at 298 K. The potential parameters are adjusted to obtain approximate agreement with experimental surface tension and partial vapor pressures for k ) 1 and 4 (84% and 57% weight percent H 2 SO 4 , respectively). The free energy differences for m e 15 are presented, together with internal cluster energy contributions, snapshots of cluster structure, and evidence for onset of the large cluster regime near m ) 5. The long-range goals have been to test the free energy difference procedure for studying binary cluster properties and to develop model potentials appropriate for the simulation of small binary clusters at low temperatures characteristic of stratospheric sulfuric acid-water aerosols.

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Section: H 2 So 4 -H 2 O Potential Modelmentioning

confidence: 99%

Monte Carlo Simulations of Small Sulfuric Acid−Water Clusters

Kathmann

Hale

2001

J. Phys. Chem. B

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“…The comparison of the uptake coefficients calculated using Equation (2) with and without enhancement factors (EF) as a function of the particle diameter for (a) free sulfuric acid molecules, (b) monohydrates, (c) dihydrates, and (d) trihydrates at the ambient gas temperature of 300 K using the same input data set as that for Figure 1. and to study the hydration effect, we compared the uptake coefficients calculated using Equations (1) and (2). Figure 1 presents the upper and lower limits of the ratio between the uptake coefficients calculated using the maximum and minimum values of the dipole moments from Table 1 (EF upper , EF lower ) and those (EF ref ) calculated using the reference measured value of the dipole moment of sulfuric acid (2.73 D; Kuczkowski et al 1981) for (a) free sulfuric acid molecules, (b) monohydrates, (c) dihydrates, and (d) trihydrates. In order to estimate the overall effect, we included in Figure 1 the calculations performed using average value of the dipole moment for each group assuming the probability of the formation of different configurations to be equal (EF average ).…”

Section: Resultsmentioning

confidence: 99%

“…Nadykto and Yu (2003) showed that the enhancement in the attachment coefficient of the neutral molecule of free sulfuric acid to small ions/charged clusters may be as big as ∼10 in the lower troposphere, ∼15 in the polar stratosphere, and ∼20 in the mesosphere due to the high dipole moment of sulfuric acid molecule. Earlier measurement of sulfuric acid dipole moment (Kuczkowski et al 1981; this work contains the only measurement to our knowledge reported in the literature) indicated that sulfuric acid molecule has a dipole moment of 2.73 D. Recent theoretical calculations by Al Natsheh et al (2003) suggested that the gas-phase sulfuric acid molecules may have different equilibrium structures that give different dipole moments. Al Natsheh et al (2003) also found that gas phase sulfuric acid hydrates have wide variations in the equilibrium structures and dipole moments.…”

Section: Introductionmentioning

confidence: 80%

“…Such a big difference in the electrical properties (up to ∼1.34, 1.58, 2.60, and 2.14 times in the dipole moments of gas-phase sulfuric acid, mono-, di-, and trihydrate, respectively) is not surprising. Based on their own measurements of the structure and electrical dipole moment, Kuczkowski et al (1981) have predicted the existence of different modifications of gas-phase sulfuric acid that lead to the variations in the hydrates' structures and properties. Despite the wide variations of the dipole moments, the total bonding energies of the structures are pretty close within each group that is believed to indicate quite close probabilities of the formation for different structures.…”

Section: Structure and Polarity Of Gas-phase Sulfuric Acid And Its Hymentioning

confidence: 99%

“…The upper and lower limits of the ratio between the uptake coefficients calculated using the maximum and minimum values of the dipole moments from Kuczkowski et al 1981) for (a) free sulfuric acid molecules, (b) monohydrates, (c) dihydrates, and (d) trihydrates.…”

Section: Uptake Coefficientsmentioning

confidence: 99%

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Effect of Molecular Structure and Hydration on the Uptake of Gas-Phase Sulfuric Acid by Charged Clusters/Ultrafine Particles

Nadykto

Natsheh

et al. 2004

Aerosol Science and Technology

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The enhanced uptake of sulfuric acid molecules by charged clusters as a result of dipole-charge interaction is critical to the ionmediated nucleation of particles in the atmosphere. This article illustrates the effect of the structure of the gas-phase sulfuric acid and its hydrates on the uptake of the sulfuric acid molecules by the charged clusters/ultrafine particles. It is shown that the different structures of gas-phase sulfuric acid and its hydrates lead to very big (up to ∼230%) variations in the uptake coefficients due to the large difference in the dipole moments. On average, the hydration of gaseous sulfuric acid in the atmosphere is likely to enhance the uptake coefficients.

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Superacidity of neutral Br�nsted acids in gas phase

Burk

Koppel

et al. 1996

J. Comput. Chem.

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Quantum chemical calculations of potentially superacidic neutral Brönsted acids were carried out using the PM3 method. It was shown that the PM3 method can be used to predict the gas phase acidities of acidic compounds only if empirical corrections are made. A strong acidifying effect is predicted for a new family of compounds in which an sp2 oxygen is substituted by an (DOUBLE BOND) NSO2CF3 group. So, for example, such replacement is expected to result in acid strengthening by 47.5 kcal/mol in the case of CH3CHO and by 22.7 kcal/mol in the case of CF3SO2OH. The acidities of such compounds are predicted to be increased further (nonadditively) by stepwise replacements of (DOUBLE BOND) O by (DOUBLE BOND) NSO2CF3. The geometries of known superacidic systems were reproduced quite well by PM3 method. The geometries of several superacidic systems were analyzed. © 1996 by John Wiley & Sons, Inc.

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Microwave spectrum, structure, and dipole moment of sulfuric acid

Cited by 144 publications

References 0 publications

Monte Carlo Simulations of Small Sulfuric Acid−Water Clusters

Monte Carlo Simulations of Small Sulfuric Acid−Water Clusters

Effect of Molecular Structure and Hydration on the Uptake of Gas-Phase Sulfuric Acid by Charged Clusters/Ultrafine Particles

Superacidity of neutral Br�nsted acids in gas phase

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