A Computational Study of the Hydration of the OH Radical

Hamad, Said; Lago, S.; Mejías, José A.

doi:10.1021/jp013531y

Cited by 59 publications

(97 citation statements)

References 58 publications

(107 reference statements)

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“…12 Several works have been carried out to analyze the interactions of the OH radical with the water molecule [13][14][15][16] and the microsolvation of the radical in water clusters. 12,17 In the present paper we report a theoretical study of the hydration of the OH radical. To carry out this study two approaches have been adopted: microsolvation modeling and Monte Carlo statistical mechanics simulations.…”

Section: Introductionmentioning

confidence: 98%

The hydration of the OH radical: Microsolvation modeling and statistical mechanics simulation

Couto

Guedes

Cabral

et al. 2003

The Journal of Chemical Physics

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The hydration of the hydroxyl OH radical has been investigated by microsolvation modeling and statistical mechanics Monte Carlo simulations. The microsolvation approach was based on density functional theory ͑DFT͒ calculations for OH-(H 2 O) 1-6 and (H 2 O) 1-7 clusters. The results from microsolvation indicate that the binding enthalpies of the OH radical and water molecule to small water clusters are similar. Monte Carlo simulations predict that the hydration enthalpy of the OH radical, ⌬ hyd H(OH,g), is Ϫ39.1 kJ mol Ϫ1. From this value we have estimated that the band gap of liquid water is 6.88 eV, which is in excellent agreement with the result of Coe et al. ͓J. Chem. Phys. 107, 6023 ͑1997͔͒. We have compared the structure of the hydrated OH solution with the structure of pure liquid water. The structural differences between the two systems reflect the strong role played by the OH radical as a proton donor in water. From sequential Monte Carlo/DFT calculations the dipole moment of the OH radical in liquid water is 2.2Ϯ0.1 D, which is ϳ33% above the experimental gas phase value ͑1.66 D͒.

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Section: Introductionmentioning

confidence: 98%

The hydration of the OH radical: Microsolvation modeling and statistical mechanics simulation

Couto

Guedes

Cabral

et al. 2003

The Journal of Chemical Physics

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“…2,3 On the other hand, the properties of the hydroxyl radical are commonly exploited by the immune system and prove advantageous in targeted anticancer therapy. [8][9][10][11][12][13][14][15][16][17][18][19] They include ab initio studies of OH in small clusters, mostly consisting of o10 water molecules, density functional theory (DFT) molecular dynamics simulations of OH-(H 2 O) 31 complexes, as well as classical molecular dynamics (MD) and Monte Carlo (MC) simulations. 5,6 Being involved in various chemical and biochemical mechanisms, the hydroxyl radical has become a target of scientific investigations.…”

Section: Introductionmentioning

confidence: 99%

“…5,6 Being involved in various chemical and biochemical mechanisms, the hydroxyl radical has become a target of scientific investigations. 10,12 The location of OH in clusters of such size is of primary interest for atmospheric chemistry, since the oxidizing activity of OH towards air pollutants, such as volatile organic compounds (VOCs) and methane, determines their lifetime and concentration in the troposphere. 7 The past decade has yielded a lot of computational studies on the hydroxyl radical in liquid water.…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics study of the hydration of the hydroxyl radical at body temperature

Pabis

Szala-Bilnik

Swiatla-Wojcik

2011

Phys. Chem. Chem. Phys.

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Classical molecular dynamics (MD) simulation of ˙OH in liquid water at 37 °C has been performed using flexible models of the solute and solvent molecules. We derived the Morse function describing the bond stretching of the radical and the potential for ˙OH-H(2)O interactions, including short-range interactions of hydrogen atoms. Scans of the potential energy surface of the ˙OH-H(2)O complex have been performed using the DFT method with the B3LYP functional and the 6-311G(d,p) basis set. The DFT-derived partial charges, ±0.375e, and the equilibrium bond-length, 0.975 Å, of ˙OH resulted in the dipole moment of 1.76 D. The radical-water radial distribution functions revealed that ˙OH is not built into the solvent structure but it rather occupies distortions or cavities in the hydrogen-bonded network. The solvent structure at 37 °C has been found to be the same as that of pure water. The hydration cage of the radical comprises 13-14 water molecules. The estimated hydration enthalpy -42 ± 5 kJ mol(-1) is comparable with the experimental value -39 ± 6 kJ mol(-1) for 25 °C. Inspection of hydrogen bonds showed the importance of short-range interaction of hydrogen atoms and indicated that neglect of the angular condition greatly overestimates the number of the H-acceptor radical-water bonds. The mean number ̅n = 0.85 of radical-water H-bonds has been calculated using geometric definition of H-bond and ̅n = 0.62 has been obtained when the energetic condition, E(da)≤-8 kJ mol(-1), was additionally considered. The continuous lifetimes of 0.033 ps and 0.024 ps have been estimated for the radical H-donor and the H-acceptor bonds, respectively. Within statistical uncertainty the radical self-diffusion coefficient, (2.9 ± 0.6) × 10(-9) m(2) s(-1), is the same as (3.1 ± 0.5) × 10(-9) m(2) s(-1) calculated for water in solution and in pure solvent. To the best of our knowledge, this is the first study of the ˙OH(aq) properties at a biologically relevant body temperature.

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“…[5][6][7][8][9][10][11][12][13][14][15][16] Hamza et al 5 studied the proton subtraction of the C4 * of a DNA sugar using an ab initio method. In this case, the charge of the OH 0 is 0.44e for the proton, and −0.44e for the oxygen.…”

Section: Introductionmentioning

confidence: 99%

“…They obtained three structures, in two of them the OH 0 acts as proton donor, and in a third it acts as proton acceptor. Hamad et al 7 studied the hydration of OH 0 in small H 2n+1 -O n ͑n =1-5͒ clusters using different quantumchemical methods. The binding energy is the largest when OH 0 acts as proton donor.…”

Section: Introductionmentioning

confidence: 99%

Classical molecular-dynamics simulation of the hydroxyl radical in water

Campo

Grigera

2005

The Journal of Chemical Physics

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Articles you may be interested in Instituto de Física de Líquidos y Sistemas Biológicos (IFLYSIB), Universidad Nacional de la Plata (UNLP)-Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET)-Comisión de Investigaciones Científicas de la Provincia de Buenos Aires (CIC), B1900BTE, LaWe have studied the hydration and diffusion of the hydroxyl radical OH 0 in water using classical molecular dynamics. We report the atomic radial distribution functions, hydrogen-bond distributions, angular distribution functions, and lifetimes of the hydration structures. The most frequent hydration structure in the OH 0 has one water molecule bound to the OH 0 oxygen ͑57% of the time͒, and one water molecule bound to the OH 0 hydrogen ͑88% of the time͒. In the hydrogen bonds between the OH 0 and the water that surrounds it the OH 0 acts mainly as proton donor. These hydrogen bonds take place in a low percentage, indicating little adaptability of the molecule to the structure of the solvent. All hydration structures of the OH 0 have shorter lifetimes than those corresponding to the hydration structures of the water molecule. The value of the diffusion coefficient of the OH 0 obtained from the simulation was 7.1ϫ 10 −9 m 2 s −1 , which is higher than those of the water and the OH − .

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A Computational Study of the Hydration of the OH Radical

Cited by 59 publications

References 58 publications

The hydration of the OH radical: Microsolvation modeling and statistical mechanics simulation

The hydration of the OH radical: Microsolvation modeling and statistical mechanics simulation

Molecular dynamics study of the hydration of the hydroxyl radical at body temperature

Classical molecular-dynamics simulation of the hydroxyl radical in water

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