Your search keyword '"Z F, Xu"' showing total 5 results

1. Ab initio studies of alkyl radical reactions: Combination and disproportionation reactions of CH3 with C2H5, and the decomposition of chemically activated C3H8

Author

Z. F. Xu, R. S. Zhu, and Ming-Chang Lin

Subjects

Reaction rate, chemistry.chemical_classification, chemistry, Ab initio quantum chemistry methods, Computational chemistry, Binding energy, Ab initio, General Physics and Astronomy, Disproportionation, Singlet state, Physical and Theoretical Chemistry, Radical disproportionation, Alkyl

Abstract

This paper reports the first quantitative ab initio prediction of the disproportionation/combination ratio of alkyl+alkyl reactions using CH3+C2H5 as an example. The reaction has been investigated by the modified Gaussian-2 method with variational transition state or Rice-Ramsperger-Kassel-Marcus calculations for several channels producing (1) CH4+CH2CH2, (2) C3H8, (3) CH4CH3CH, (4) H2+CH3CHCH2, (5) H2+CH3CCH3, and (6) C2H6+CH2 by H-abstraction and association/decomposition mechanisms through singlet and triplet potential energy paths. Significantly, the disproportionation reaction (1) producing CH4+C2H4 was found to occur primarily by the lowest energy path via a loose hydrogen-bonding singlet molecular complex, H3CHC2H4, with a 3.5 kcal/mol binding energy and a small decomposition barrier (1.9 kcal/mol), instead of a direct H-abstraction process. Bimolecular reaction rate constants for the formation of the above products have been calculated in the temperature range 300-3000 K. At 1 atm, formation of C3H8 is dominant below 1200 K. Over 1200 K, the disproportionation reaction becomes competitive. The sum of products (3)-(6) accounts for less than 0.3% below 1500 K and it reaches around 1%-4% above 2000 K. The predicted rate constant for the disproportionation reaction with multiple reflections above the complex well, k1=5.04 x T(0.41) exp(429/T) at 200-600 K and k1=1.96 x 10(-20) T(2.45) exp(1470/T) cm3 molecule(-1) s(-1) at 600-3000 K, agrees closely with experimental values. Similarly, the predicted high-pressure rate constants for the combination reaction forming C3H8 and its reverse dissociation reaction in the temperature range 300-3000 K, k2(infinity)=2.41 x 10(-10) T(-0.34) exp(259/T) cm3 molecule(-1) s(-1) and k(-2)(infinity)=8.89 x 10(22) T(-1.67)exp(-46 037/T) s(-1), respectively, are also in good agreement with available experimental data.

Published

2004

2. Ab initio studies of ClOx reactions. IX. Combination and disproportionation reactions of ClO and s-ClO3 radicals

Author

Ming-Chang Lin and Z. F. Xu

Subjects

Reaction rate constant, Ab initio quantum chemistry methods, Chemistry, Radical, Ab initio, General Physics and Astronomy, Disproportionation, Singlet state, Physical and Theoretical Chemistry, Triplet state, Photochemistry, Standard enthalpy of formation

Abstract

The mechanism for the reaction ClO+ClO3 on both singlet and triplet state potential surfaces has been investigated with the modified Gaussian-2 method based on the B3LYP/6-311+G(3df ) optimized stationary-point geometries. The result shows that the barrierless association reaction producing ClOClO3 and two lower barrier O-atom abstraction reactions take place primarily on the singlet state potential surface; they are energetically more favorable than those occurring on the triplet state surface. Rate constants calculated by variational transition state and Rice–Ramsperger–Kassel–Marcus theories suggest that the major products are ClOClO3 at low temperatures (

Published

2003

3. Thermal decomposition of ethanol. II. A computational study of the kinetics and mechanism for the H+C2H5OH reaction

Author

Ming-Chang Lin, Z. F. Xu, and J. Park

Subjects

Chemical kinetics, Reaction rate constant, Chemistry, Kinetics, Thermal decomposition, General Physics and Astronomy, Thermodynamics, Physical chemistry, Physical and Theoretical Chemistry, Atmospheric temperature range, Combustion, Chemical decomposition, Transition state

Abstract

The kinetics and mechanism for the H+C2H5OH reaction, a key chain-propagation step in the high temperature decomposition and combustion of ethanol, have been investigated with the modified GAUSSIAN -2 (G2M) method using the structures of the reactants, transition states and products optimized at the B3LYP/6-311+G(d,p) level of theory. Four transition states have been identified for the production of H2+CH3CHOH (TS1), H2+CH2CH2OH (TS2), H2+C2H5O (TS3), and H2O+C2H5 (TS4) with the corresponding barriers, 7.18, 13.30, 14.95, and 27.10 kcal/mol. The predicted rate constants and branching ratios for the three H-abstraction reactions have been calculated over the temperature range 300–3000 K using the conventional and variational transition state theory with quantum-mechanical tunneling corrections. The predicted total rate constant, kt=3.15×103T3.12 exp(−1508/T) cm3 mol−1 s−1, agrees reasonably with existing experimental data; in particular, the result at 423 K was found to agree quantitatively with an availab...

Published

2003

4. Ab initio studies of ClOx reactions. I. Kinetics and mechanism for the OH+ClO reaction

Author

Z. F. Xu, Ming-Chang Lin, and R. S. Zhu

Subjects

Chemical kinetics, Reaction rate constant, Computational chemistry, Chemistry, Ab initio quantum chemistry methods, Ab initio, General Physics and Astronomy, Physical chemistry, Molecular orbital, Singlet state, Physical and Theoretical Chemistry, Atmospheric temperature range, Standard enthalpy of formation

Abstract

The reaction of OH with ClO has been investigated by ab initio molecular orbital and variational transition state theory calculations. Both singlet and triplet potential energy surfaces predicted by the G2M method are presented. The reaction was shown to take place primarily over the singlet surface by two main channels producing HO2+Cl and HCl+O2(1Δ), with the former being dominant. The predicted total rate constant, kt=5.27×10−9 T1.03 exp (−40/T) cm3 molecule−1 s−1, and product branching ratios in the temperature range 200–500 K at P

Published

2002

5. Dynamics of the reactions of O(1D) with CD3OH and CH3OD studied with time-resolved Fourier-transform IR spectroscopy

Author

Soji Tsuchiya, Yuan-Pern Lee, Chong Kai Huang, Hue Minh Thi Nguyen, Z. F. Xu, Ming-Chang Lin, and Masakazu Nakajima

Subjects

Hydrogen, chemistry, Intramolecular force, Excited state, Kinetic isotope effect, Vibrational energy relaxation, Analytical chemistry, General Physics and Astronomy, Infrared spectroscopy, chemistry.chemical_element, Reactivity (chemistry), Physical and Theoretical Chemistry, Dissociation (chemistry)

Abstract

We investigated the reactivity of O((1)D) towards two types of hydrogen atoms in CH(3)OH. The reaction was initiated on irradiation of a flowing mixture of O(3) and CD(3)OH or CH(3)OD at 248 nm. Relative vibration-rotational populations of OH and OD (1 ≤ v ≤ 4) states were determined from their infrared emission recorded with a step-scan time-resolved Fourier-transform spectrometer. In O((1)D) + CD(3)OH, the rotational distribution of OD is nearly Boltzmann, whereas that of OH is bimodal; the product ratio [OH]/[OD] is 1.56 ± 0.36. In O((1)D) + CH(3)OD, the rotational distribution of OH is nearly Boltzmann, whereas that of OD is bimodal; the product ratio [OH]/[OD] is 0.59 ± 0.14. Quantum-chemical calculations of the potential energy and microcanonical rate coefficients of various channels indicate that the abstraction channels are unimportant and O((1)D) inserts into the C-H and O-H bonds of CH(3)OH to form HOCH(2)OH and CH(3)OOH, respectively. The observed three channels of OH are consistent with those produced via decomposition of the newly formed OH or the original OH moiety in HOCH(2)OH or decomposition of CH(3)OOH. The former decomposition channel of HOCH(2)OH produces vibrationally more excited OH because of incomplete intramolecular vibrational relaxation, and decomposition of CH(3)COOH produces OH with greater rotational excitation, likely due to a large torque angle during dissociation. The predicted [OH]/[OD] ratios are 1.31 and 0.61 for O((1)D) + CD(3)OH and CH(3)OD, respectively, at collision energy of 26 kJ mol(-1), in satisfactory agreement with the experimental results. These predicted product ratios vary weakly with collision energy.

Published

2012