The time dependence of rate coefficients and fluorescence anisotropy for non-delta production

A laser-flash photolysis/UV absorption technique has been used to study the temperature dependence (from T ϭ 300 -470 K) of the self-reaction kinetics of representative primary, secondary, and tertiary ␤-hydroxyperoxy radicals: The following Arrhenius expressions were derived for the rate coefficie

or from the thermal decomposition of larger radicals formed in the degradation of oxygenated hydrocarbons, e.g., the OH-initiated oxidation of methylglyoxal [2]: (2)

Rate coefficients for the reaction of Cl atoms with CH 3 Cl (k 1 ), CH 2 Cl 2 (k 2 ), and CHCl 3 (k 3 ) have been determined over the temperature range 222-298 K using standard relative rate techniques. These data, when combined with evaluated data from previous studies, lead to the following Arrhen

Flyorescence decay times of the di-, tri-, tetra-and pentwnethyl benzenes and the three isomeric difiuorobenzencs have been rncnsured at low pressures. The substitucnt effects of CH3+roups and F-atom (in benzene) on the nonrndiativc rate ofrhc "isolated" ascited singlet molecule are briefly discusse

## Abstract The rate coefficient for the gas‐phase reaction of chlorine atoms with acetone was determined as a function of temperature (273–363 K) and pressure (0.002–700 Torr) using complementary absolute and relative rate methods. Absolute rate measurements were performed at the low‐pressure regi