Your search keyword '"STAR-FORMING REGIONS"' showing total 3 results

1. Theoretical study on the reaction mechanism of cyclopropenylidene with cyclic CnH2nO (n = 2, 3) compounds: Ring expansion process

Author

Xiaojun Tan, Weihua Wang, and Ping Li

Subjects

Interstellar molecule, Star-forming regions, Circumstellar envelopes, Thermodynamics, Kinetics, Chemistry, QD1-999

Abstract

The ring expansion reaction mechanisms between cyclopropenylidene and cyclic CnH2nO (n = 2, 3) compounds have been systematically investigated employing the second-order Møller-Plesset perturbation theory (MP2) method in order to better understand the reactivity of cyclopropenylidene with epoxy compounds (oxirane and epoxypropane). Geometry optimizations and vibration analyses have been performed for the stationary points on the potential energy surfaces of the system. The calculated results show that cyclopropenylidene can insert into oxirane at its CO bond and into epoxypropane at its CO or CC bond. From the kinetic viewpoint, it is easier for cyclopropenylidene to insert into the CO bond of oxirane than that of the CO bond of epoxypropane. For insertion into epoxypropane, it is easier for cyclopropenylidene to insert into its CO bond than CC bond. Through the first insertion step and the second ring-opened step, spiro and carbene intermediates can been formed between cyclopropenylidene and epoxy compounds, respectively. Through the following two H-transfer steps, carbene intermediate forms the products of allenes and alkynes, respectively. From the thermodynamics viewpoint, the allenes are the dominant product for the title reaction.

Published

2016

2. Theoretical study on the reaction mechanism of cyclopropenylidene with cyclic CnH2nO (n = 2, 3) compounds: Ring expansion process.

Author

Tan, Xiaojun, Wang, Weihua, and Li, Ping

Abstract

The ring expansion reaction mechanisms between cyclopropenylidene and cyclic C n H 2 n O ( n = 2, 3) compounds have been systematically investigated employing the second-order Møller-Plesset perturbation theory (MP2) method in order to better understand the reactivity of cyclopropenylidene with epoxy compounds (oxirane and epoxypropane). Geometry optimizations and vibration analyses have been performed for the stationary points on the potential energy surfaces of the system. The calculated results show that cyclopropenylidene can insert into oxirane at its C O bond and into epoxypropane at its C O or C C bond. From the kinetic viewpoint, it is easier for cyclopropenylidene to insert into the C O bond of oxirane than that of the C O bond of epoxypropane. For insertion into epoxypropane, it is easier for cyclopropenylidene to insert into its C O bond than C C bond. Through the first insertion step and the second ring-opened step, spiro and carbene intermediates can been formed between cyclopropenylidene and epoxy compounds, respectively. Through the following two H-transfer steps, carbene intermediate forms the products of allenes and alkynes, respectively. From the thermodynamics viewpoint, the allenes are the dominant product for the title reaction. [ABSTRACT FROM AUTHOR]

Published

2016

3. Theoretical study on the reaction mechanism of cyclopropenylidene with cyclic CnH2nO (n=2, 3) compounds: Ring expansion process

Author

Ping Li, Xiaojun Tan, and Weihua Wang

Subjects

Cyclopropenylidene, Reaction mechanism, Chemistry(all), Stereochemistry, Kinetics, 010402 general chemistry, Ring (chemistry), Kinetic energy, Interstellar molecule, 01 natural sciences, lcsh:Chemistry, chemistry.chemical_compound, Computational chemistry, Reactivity (chemistry), Star-forming regions, GeneralLiterature_REFERENCE(e.g.,dictionaries,encyclopedias,glossaries), ComputingMilieux_MISCELLANEOUS, 010405 organic chemistry, General Chemistry, Potential energy, Circumstellar envelopes, 0104 chemical sciences, lcsh:QD1-999, chemistry, Thermodynamics, Carbene

Abstract

The ring expansion reaction mechanisms between cyclopropenylidene and cyclic CnH2nO (n = 2, 3) compounds have been systematically investigated employing the second-order Moller-Plesset perturbation theory (MP2) method in order to better understand the reactivity of cyclopropenylidene with epoxy compounds (oxirane and epoxypropane). Geometry optimizations and vibration analyses have been performed for the stationary points on the potential energy surfaces of the system. The calculated results show that cyclopropenylidene can insert into oxirane at its C O bond and into epoxypropane at its C O or C C bond. From the kinetic viewpoint, it is easier for cyclopropenylidene to insert into the C O bond of oxirane than that of the C O bond of epoxypropane. For insertion into epoxypropane, it is easier for cyclopropenylidene to insert into its C O bond than C C bond. Through the first insertion step and the second ring-opened step, spiro and carbene intermediates can been formed between cyclopropenylidene and epoxy compounds, respectively. Through the following two H-transfer steps, carbene intermediate forms the products of allenes and alkynes, respectively. From the thermodynamics viewpoint, the allenes are the dominant product for the title reaction.