Your search keyword '"Xiumei Pan"' showing total 3 results

1. Theoretical study for the reaction of CH3CN with O(3P).

Author

Jingyu Sun, Yizhen Tang, Xiujuan Jia, Fang Wang, Hao Sun, Jingdong Feng, Xiumei Pan, Lizhu Hao, and Rongshun Wang

Subjects

POTENTIAL energy surfaces, CHEMICAL reactions, CARBON compounds, QUANTUM chemistry, HYDROGEN, NITROGEN

Abstract

The low-lying triplet and singlet potential energy surfaces of the O(3P)+CH3CN reaction have been studied at the G3(MP2)//B3LYP/6-311+G(d,p) level. On the triplet surface, six kinds of pathways are revealed, namely, direct hydrogen abstraction, C-addition/elimination, N-addition/elimination, substitution, insertion, and H-migration. Multichannel Rice–Ramsperger–Kassel–Marcus theory and transition-state theory are employed to calculate the overall and individual rate constants over a wide range of temperatures and pressures. It is predicted that the direct hydrogen abstraction and C-addition/elimination on triplet potential energy surface are dominant pathways. Major predicted end products include CH3+NCO and CH2CN+OH. At atmospheric pressure with Ar and N2 as bath gases, CH3C(O)N (IM1) formed by collisional stabilization is dominated at T<700 K, whereas CH3 and NCO produced by C-addition/elimination pathway are the major products at the temperatures between 800 and 1500 K; the direct hydrogen abstraction leading to CH2CN+OH plays an important role at higher temperatures in hydrocarbon combustion chemistry and flames, with estimated contribution of 64% at 2000 K. Furthermore, the calculated rate constants are in good agreement with available experimental data over the temperature range 300–600 K. The kinetic isotope effect has also been calculated for the triplet O(3P)+CH3CN reaction. On the singlet surface, the atomic oxygen can easily insert into C–H or C–C bonds of CH3CN, forming the insertion intermediates s-IM8(HOCH2CN) and s-IM5(CH3OCN) or add to the carbon atom of CN group in CH3CN, forming the addition intermediate s-IM1(CH3C(O)N); both approaches were found to be barrierless. It is indicated that the singlet reaction exhibits a marked difference from the triplet reaction. This calculation is useful to simulate experimental investigations of the O(3P)+CH3CN reaction in the singlet state surface. [ABSTRACT FROM AUTHOR]

Published

2010

2. Mechanistic and kinetic investigations of N2H4 + OH reaction.

Author

YIZHEN TANG, JINGYU SUN, XIUJUAN JIA, HAO SUN, XIUMEI PAN, and RONGSHUN WANG

Subjects

CHEMICAL reactions, HYDRAZINE, HYDROGEN, THERMODYNAMICS, TEMPERATURE

Abstract

The reaction of N2H4 with OH has been investigated by quantum chemical methods. The results show that hydrogen abstraction mechanism is more feasible than substitution mechanism thermodynamically. The calculated rate constants agree with the available experimental data. The calculated results show that the variational effect is small at lower temperature region, while it becomes significant at higher temperature region. On the other hand, the small-curvature tunneling effect may play an important role in the temperature range 220-3000 K. Moreover, the calculated rate constants show negative temperature dependence at the temperatures below 500 K, which is in accordance with Vaghjiani's report that slightly negative temperature dependence is found over the temperature range of 258-637 K. The mechanism of the major product (N2H3) with OH has also been investigated theoretically to understand the title reaction thoroughly. © 2009 Wiley Periodicals, Inc. J Comput Chem, 2010 [ABSTRACT FROM AUTHOR]

Published

2010

3. Theoretical Investigation of the Reaction of CF3CHFOCH3with OH Radical.

Author

Hao Sun, Hongwei Gong, Xiumei Pan, Lizhu Hao, ChiaChung Sun, Rongshun Wang, and Xuri Huang

Subjects

*REACTION mechanisms (Chemistry), *CHEMICAL kinetics, *HYDROXYL group, *POTENTIAL energy surfaces, *TEMPERATURE effect, *CHEMICAL reactions, *HEAT of formation

Abstract

A direct ab initio dynamics method was used to study the mechanism and kinetics of the reaction CF3CHFOCH3+ OH. Two reaction channels, R1 and R2, were found, corresponding to H-abstraction from a CH3group and a CHF group, respectively. The potential energy surface (PES) information was obtained at the G3(MP2)//MP2/6-311G(d,p) level. The standard enthalpies of formation for the reactant (CF3CHFOCH3) and products (CF3CHFOCH2and CF3CFOCH3) were evaluated via isodesmic reactions at the same level. Furthermore, the rate constants of two channels were calculated using the canonical variational transition state theory (CVT) with small-curvature tunneling (SCT) contributions over a wide temperature range of 200−3000 K. The dynamic calculations demonstrate that reaction R1 dominates the overall reaction when the temperature is lower than 800 K whereas reaction R2 becomes more competitive in the higher temperature range. The calculated rate constants and branching ratios are both in good agreement with the available experimental values. [ABSTRACT FROM AUTHOR]

Published

2009