Chemical and electronic branching ratios in the chemiluminescent reactions of hyperthermal Ca(3P) atoms with CF2Cl2 or CF2=CCl2

G. A. PINO; C. A. RINALDI; J. C. FERRERO

JOURNAL OF PHYSICAL CHEMISTRY A

AMER CHEMICAL SOC

Año: 2003 vol. 107 p. 6761 - 6769

1089-5639

Chemiluminescent reactions of hyperthermal Ca(3P) with CF2Cl2 and CF2dCCl2 were studied in a beam-gas arrangement under single collision conditions. Emissions associated with the A(2¦¿) f X(2ª+) and the B(2ª+)3P) with CF2Cl2 and CF2dCCl2 were studied in a beam-gas arrangement under single collision conditions. Emissions associated with the A(2¦¿) f X(2ª+) and the B(2ª+)2¦¿) f X(2ª+) and the B(2ª+) f X(2ª+) transitions from CaCl and CaF were observed for both reactions. The chemical and electronic branching ratios were determined for these reactions, and different results were obtained for each one. The different behavior was rationalized by a simple MO pictures. For the case of the reaction with CF2Cl2 it was assumed that an electron from Ca(3P) is transferred to a ó*(C-Cl) orbital in CF2Cl2 which, at higher translational energies can also enter into a ó*(C-F) orbital of the same molecule. In both cases the molecular anion produced is short-lived and will undergo fast decay to Cl- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.X(2ª+) transitions from CaCl and CaF were observed for both reactions. The chemical and electronic branching ratios were determined for these reactions, and different results were obtained for each one. The different behavior was rationalized by a simple MO pictures. For the case of the reaction with CF2Cl2 it was assumed that an electron from Ca(3P) is transferred to a ó*(C-Cl) orbital in CF2Cl2 which, at higher translational energies can also enter into a ó*(C-F) orbital of the same molecule. In both cases the molecular anion produced is short-lived and will undergo fast decay to Cl- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.2Cl2 it was assumed that an electron from Ca(3P) is transferred to a ó*(C-Cl) orbital in CF2Cl2 which, at higher translational energies can also enter into a ó*(C-F) orbital of the same molecule. In both cases the molecular anion produced is short-lived and will undergo fast decay to Cl- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.3P) is transferred to a ó*(C-Cl) orbital in CF2Cl2 which, at higher translational energies can also enter into a ó*(C-F) orbital of the same molecule. In both cases the molecular anion produced is short-lived and will undergo fast decay to Cl- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.ó*(C-F) orbital of the same molecule. In both cases the molecular anion produced is short-lived and will undergo fast decay to Cl- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.- or F- to yield CaCl and CaF. For the reaction with CF2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.2dCCl2 the electron from Ca(3P) is transferred to a ð* orbital of the reagent molecule that generates a relatively stable molecular anion with 2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.2¦ symmetry. This anion subsequently cross over several repulsive 2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.2ª surfaces associated with ó* orbitals of the C-Cl and the C-F bonds, to dissociate into Cl- or F- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.- to produce CaCl and CaF. The electronic branching ratios are in good agreement with statistical distribution based on information theory approach, assuming the rigid rotor harmonic oscillator (RROH) approximation for the reaction with CF2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.2Cl2 and the formation of a collision complex for the reaction with CF2dCCl2.