TOTAL REACTION CROSS-SECTIONS OF ELECTRONIC STATE-SPECIFIED TRANSITION-METAL CATIONS - V++C2H6, C3H8, AND C2H4 AT 0.2 EV

We describe a crossed beam experiment which measures total cross sections for reaction of electronic state-specified V+ with small hydrocarbons at well-defined collision energy E = 0.2 eV. The V+ state distribution created at each ionizing wavelength is directly measured by angle-integrated photoelectron spectroscopy (preceding paper). Reactant and product ions are collected and analyzed by pulsed time-of-flight mass spectrometry following a reaction time of 6 μs. Tests of the performance of the apparatus are described in detail. Our experiment defines the reactant V+ electronic state distribution and the collision energy much more precisely than previous work. For all three hydrocarbons C2H 6, C3H8, and C2H4, H 2 elimination products dominate at 0.2 eV. We observe a dramatic dependence of cross section on the V+ electronic term. The second excited term 3d 34s(3F) is more reactive than either lower energy quintet term 3d4(5D) or 3d34s( 5F) by a factor of ≥270, 80, and ≥6 for the C2H 6, C3H8, and C2H4 reactions, respectively. The 3d34s(3F) reaction cross sections at 0.2 eV are 20 ± 11 Å2, 37 ± 19 Å2, and 2.7 ± 1.6 Å2, respectively, compared with Langevin cross sections of ∼80 Å2. For the C2H6 and C3H8 reactions, cross sections are independent of initial spin-orbit level J within the 3F term to the limits of our accuracy. Comparison with earlier work by Armentrout and co-workers shows that electronic excitation to d3s(3F) is far more effective at promoting H2 elimination than addition of the same total kinetic energy to reactants. Electron spin is clearly a key determinant of V+ reactivity with small hydrocarbons. We suggest that triplet V+ reacts much more efficiently than quintet V+ because of its ability to conserve total electron spin along paths to insertion in a C-H bond of the hydrocarbon. © 1990 American Institute of Physics.