Unraveling the dynamics of the C(3P,1D)+C2H2 reactions by the crossed molecular beam scattering technique

A detailed investigation of the dynamics of the reactions of ground- and excited-state carbon atoms, C(P-3) and C(ID), with acetylene is reported over a wide collision energy range (3.6-49.1 kJ mol(-1)) using the crossed molecular beam (CMB) scattering technique with electron ionization mass spectrometric detection and time-of-flight (TOF) analysis. We have exploited the capability of (a) generating continuous intense supersonic beams of C(P-3, D-1), (b) crossing the two reactant beams at different intersection angles (45, 90, and 135 degrees) to attain a wide range of collision energies, and (c) tuning the energy of the ionizing electrons to low values (soft ionization) to suppress interferences from dissociative ionization processes. From angular and TOF distribution measurements of products at m/z=37 and 36, the primary reaction products of the C(P-3) and C(D-1) reactions with C2H2 have been identified to be cyclic (c)-C3H + H, linear (I)-C3H + H, and C-3 + H-2. From the data analysis, product angular and translational energy distributions in the center-of-mass (CM) system for both the linear and cyclic C3H isomers as well as the C-3 product from C(P-3) and for I/c-C3H and C-3 from C(D-1) have been derived as a function of collision energy from 3.6 to 49.1 kJ mol(-1). The cyclic/linear C3H ratio and the C-3/(C-3 + c/I-C3H) branching ratios for the C(P-3) reaction have been determined as a function of collision energy. The present findings have been compared with those from previous CMB studies using pulsed beams; here, a marked contrast is noted in the CM angular distributions for both CMB and C-3-forming channels from C(P-3) and their trend with collision energy. Consequently, the interpretation of the reaction dynamics derived in the present work contradicts that previously proposed from the pulsed CMB studies. The results have been discussed in the light of the available theoretical information on the relevant triplet and singlet C3H2 ab initio potential energy surfaces (PESs). In particular, the branching ratios for the C(P-3) + C2H2 reaction have been compared with the available theoretical predictions (approximate quantum scattering calculations and quasiclassical trajectory calculations on ab initio triplet PESs and, very recent, statistical calculations on ab initio triplet PESs as well as on ab initio triplet/singlet PESs including nonadiabatic effects, that is, intersystem crossing). While the experimental branching ratios have been corroborated by the statistical predictions, strong disagreement has been found with the results of the dynamical calculations. The astrophysical implications of the present results have been noted.