Abstract
A kinetic study is presented of the reaction between lithium atoms and hydrogen chloride over the temperature range 700–1000 K. Li atoms are produced in an excess of HCl and He bath gas by pulsed photolysis of LiCl vapor. The concentration of the metal atoms is then monitored in real time by the technique of laser-induced fluorescence of Li atoms at λ=670.7 nm using a pulsed nitrogen-pumped dye laser and box-car integration of the fluorescence signal. Absolute second-order rate constants for this reaction have been measured at T=700, 750, 800, and 900 K. At T=1000 K the reverse reaction is sufficiently fast that equilibrium is rapidly established on the time scale of the experiment. A fit of the data between 700 and 900 K to the Arrhenius form, with 2σ errors calculated from the absolute errors in the rate constants, yields k(T)=(3.8±1.1)×10−10 exp[−(883±218)/T] cm3 molecule−1 s−1. This result is interpreted through a modified form of collision theory which is constrained to take account of the conservation of total angular momentum during the reaction. Thereby we obtain an estimate for the reaction energy threshold, E0=8.2±1.4 kJ mol−1 (where the error arises from uncertainty in the exothermicity of the reaction), in very good agreement with a crossed molecular beam study of the title reaction, and substantially lower than estimates of E0 from both semiempirical and ab initio calculations of the potential energy surface.
Highlights
Powered by the California Digital Library University of CaliforniaA study of the reaction Li+ HCI by the technique of time-resolved laserinduced fluorescence spectroscopy of Li (2 2PJ-2 25 112, A.=670.7 nm) between 700 and 1000 K
The reactions between the alkali metals and the hydrogen halides have played a central role in the development of reaction dynamics since the 1930's, when they were first studied by the diffusion flame technique
1 Generally characterized by large reaction cross sections, this class ofreactions was a primary candidate for pioneering the molecular beam technique: the first chemical reaction to be studied in crossed molecular beams was the K + HBr system, investigated in 1955 by Taylor and Datz,[2] and many other reactions between the alkali atoms and hydrogen halides have been studied subsequently by this method.[3]
Summary
A study of the reaction Li+ HCI by the technique of time-resolved laserinduced fluorescence spectroscopy of Li (2 2PJ-2 25 112, A.=670.7 nm) between 700 and 1000 K. A fit of the data between 700 and 900 K to the Arrhenius form, with 20' errors calculated from the absolute errors in the rate constants, yields k(T) = (3.8 ± l.l) X 10- 10 exp[ - (883 ± 218)/TJ cm[3] molecule- s - 1. This result is interpreted through a modified form of collision theory which is constrained to take account of the conservation of total angular momentum during the reaction.
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