Energy partitioning in O(1D2) reactions. I. O(D1D2) + H2S → OH(ν′) + HS

The product hydroxyl radical arising from the reaction 0( 1D 2)-t-H 2 ---, OH + H was detected by LIF following excitation of the off-diagonal transition OH(A2E +, v' = 1 6-X 2II, v" = 2) in the region 348-357 nm. The rotational population distribution in v" = 2 appears to be inverted and quite simi

Rate coefficients, in units of 10-~0 cm 3 molecule-~ s-~, for the O(~D) reactions with H2, D 2 and HD at 298 K were determined to be 1.2 \_\_\_ 0.1, 1.1 + 0.1, and 1.2 + 0.1, respectively. The H atom yield in the O(~ D) + HD reaction, relative to that in the O(ID) + H 2 reaction, was measured to be

The energy disu-ibulion or nascent OH('n. v. J) produced in the reaclien o. r O('D) wilh H,S has been measured by leser-lnduccd fluorescence. The rolaGanal distributions in u"= 0 and U" -1 are Bollunannran with lemperalure paramewrs T; \_,-23C+O+IOOKand7;-\_,= 2650\*150 K A population ratio N(u"=l)/

The internal energy of the excited BaO formed in the reaction between Ba(6s5d 'D2) and an OZ molecule has been studied in a crossed beam apparatus as a function of the collision energy. It is found to be statistically distributed even at a collision energy as high as 0.58 eV. By comparison with the