Your search keyword '"Melissas, Vasilios S."' showing total 5 results

1. An experimental and theoretical study of the S1←S0 transition of p-ethynyltoluene.

Author

Philis, John G. and Melissas, Vasilios S.

Subjects

*SPECTRUM analysis, *FLUIDS, *NUCLEAR physics, *GEOMETRY, *RESONANCE

Abstract

The one photon and the two photon S1←S0 spectra of jet-cooled p-ethynyltoluene have been measured for the first time, and a detailed vibronic analysis for both spectra has been attained. Mass analyzed resonance enhanced multiphoton ionization spectroscopy is the employed technique. In the one photon spectrum, the allowed component (origin and Franck-Condon bands) is much weaker than the forbidden component, and the same mechanisms as in the one photon spectrum of phenylacetylene are observed. The methyl torsional transitions are active. The 000 band is at 35 483 cm-1. The two photon spectrum is very strong and bears a resemblance to the two photon spectrum of phenylacetylene. The potential barrier of the methyl rotor in the S1 state has been determined as V6=-12 cm-1 with BCH3=5.55 cm-1. Ab initio calculations, MP2(full)/cc-pVTZ and CAS/cc-pVTZ, have been implemented for the geometry optimization and the normal mode vibration computation in the S0 and S1 states. [ABSTRACT FROM AUTHOR]

Published

2007

2. Deuterium and carbon-13 kinetic isotope effects for the reaction of OH with CH4.

Author

Melissas, Vasilios S. and Truhlar, Donald G.

Subjects

*DEUTERIUM, *CARBON, *ISOTOPES, *CHEMICAL reactions, *HYDROXIDES

Abstract

Interpolated variational transition state theory calculations with centrifugal-dominant, small-curvature tunneling coefficients have been carried out for the case of the deuterium kinetic isotope effect (KIE) in the reaction OH+12CD4→HDO+12CD3 and for the 13C KIE for the reaction OH+13CH4→H2O+13CH3. The interpolated variationally optimized generalized transition states predict notably different nontunneling KIEs than the conventional ones, and factorization analyses of the KIEs are presented to illustrate the origin of the differences. The zero-point energies at the variational transition states differ from those at the saddle point by up to 0.19 kcal/mol for the OH+12CD4 reaction and by up to 0.34 kcal/mol for the OH+13CH4 reaction. The incorporation of multidimensional tunneling effects partly cancels the effect of variational optimization of the transition state. [ABSTRACT FROM AUTHOR]

Published

1993

3. Interpolated variational transition state theory and tunneling calculations of the rate constant of the reaction OH+CH4 at 223–2400 K.

Author

Melissas, Vasilios S. and Truhlar, Donald G.

Subjects

*INTERPOLATION, *QUANTUM tunneling, *PERTURBATION theory, *HYDROCARBONS, *HYDROXYL group

Abstract

We have carried out ab initio calculations for the reaction OH+CH4→H2O+CH3 using second-order Mo\ller–Plesset perturbation theory, employing a very large basis set and scaling all correlation energy for the final energy calculation, but optimizing the equilibrium and transition state structures without scaling (MP-SAC2//MP2). We found that inclusion of correlation energy has an important effect on the geometry, barrier height, and vibrational frequencies of the transition state. The final calculated values for the forward and reverse classical barrier heights are 7.4 and 20.6 kcal/mol, respectively. We have used these with interpolated canonical variational transition state theory and the centrifugal-dominant small-curvature tunneling approximation, including information at the reactants, products, transition state, and two other points along the minimum energy path, to predict the rate constants for the above reaction in the temperature range from 223 to 2400 K. The calculated rate constants agree well with experiment over a wide temperature range. [ABSTRACT FROM AUTHOR]

Published

1993

4. Optimized calculations of reaction paths and reaction-path functions for chemical reactions.

Author

Melissas, Vasilios S., Truhlar, Donald G., and Garrett, Bruce C.

Subjects

*CHEMICAL reactions, *ALGORITHMS

Abstract

In this paper we optimize several algorithms for the computation of reaction rates based on information calculated along minimum energy reaction paths and we evaluate the efficiencies of the optimized algorithms. The investigations are based on the calculation of chemical reaction rate constants using variational transition state theory and multidimensional semiclassical transmission coefficients including reaction path curvature. Several methods are evaluated and compared by a systematic set of applications to test cases involving the hydrogen-atom transfer reactions CH3+H2→CH4+H and OH+H2→H2O+H. For each method we present general recommendations for all algorithmic choices other than gradient step size so that future calculations may be carried out reasonably efficiently by varying only one parameter. In the process of these optimizations we have found that the accuracy of the Euler stabilization method can be significantly increased by choosing the auxiliary parameters differently than in previous work; the optimized algorithm is called ES1*. Our final recommendations for future work are (i) when the Hessian/gradient computational cost ratio is low (<=3): the Page–McIver algorithm with the Hessian recalculated at every step, with a cubic starting step, and with curvature calculated from the derivative of the gradient, and (ii) when the Hessian/gradient computational cost ratio is moderate or large: the ES1* algorithm with a Hessian step size three times larger than the gradient step size, with a quadratic starting step, and with curvature calculated from the derivative of the gradient. [ABSTRACT FROM AUTHOR]

Published

1992

5. An experimental and theoretical study of the S(1)<--S0 transition of p-ethynyltoluene.

Author

Philis JG and Melissas VS

Subjects

Photons, Rotation, Spectrometry, Mass, Electrospray Ionization methods, Vibration, Computer Simulation, Models, Chemical, Quantum Theory, Toluene analogs & derivatives, Toluene chemistry

Abstract

The one photon and the two photon S(1)<--S(0) spectra of jet-cooled p-ethynyltoluene have been measured for the first time, and a detailed vibronic analysis for both spectra has been attained. Mass analyzed resonance enhanced multiphoton ionization spectroscopy is the employed technique. In the one photon spectrum, the allowed component (origin and Franck-Condon bands) is much weaker than the forbidden component, and the same mechanisms as in the one photon spectrum of phenylacetylene are observed. The methyl torsional transitions are active. The 0(0) (0) band is at 35 483 cm(-1). The two photon spectrum is very strong and bears a resemblance to the two photon spectrum of phenylacetylene. The potential barrier of the methyl rotor in the S(1) state has been determined as V(6)=-12 cm(-1) with B(CH(3) )=5.55 cm(-1). Ab initio calculations, MP2(full)/cc-pVTZ and CAS/cc-pVTZ, have been implemented for the geometry optimization and the normal mode vibration computation in the S(0) and S(1) states.

Published

2007