Kinetics of formation and removal of atomic halogen ions X
            -
            by HX + e ⇄ H + X
            -
            in atmospheric pressure flames for chlorine, bromine and iodine

The ions present in a variety of flames have been studied by continuously pumping a small fraction of the hot gases through a small hole and expanding it supersonically inside a conical duct to the low pressures required for mass spectrometric analysis. We conclude from measurements of ion abundances that if a halogen X is added to a flame containing free electrons, then the negative ion X - is produced by dissociative attachment in the forward step of HX + e - ⇄X - +H. Reaction (I) is found to be rapid enough to be equilibrated in the burnt gases. This method of sampling imposes a rapid drop in temperature and pressure on the gas as it expands and typically there is a fall of roughly 1400 K and 99 kPa in the first 10 -7 s. An equilibrium such as (I) relaxes to some extent to these falling temperatures, but at a distance of around two orifice diameters inside the expansion no further shift of (1) is possible. A comparison of a measured [X - ] with one computed on the basis of (I) being equilibrated in the flame gives a quantitative measure of the extent to which the reaction shifts during sampling. In addition, the flame sample is often also cooled as it passes through boundary layers immediately before entering the instrument. We conclude however that this effect is of little consequence, provided a large enough sampling hole (diameter > 0.15 mm) is used. In this case the measured shift of (I) can be compared with values of it predicted on the basis of guessed velocity constants for the backward process in (I) and also a one-dimensional adiabatic treatment of the expansion. This comparison provides values for the rate constants and of both steps in (I). The magnitudes of k -1 for the back reaction over the temperature range 1800—2650 K are 7 x 10 -10 , 8 x 10 -10 and 10 x 10 -10 ml molecule -1 s -1 for chlorine, bromine and iodine, respectively (with uncertainties corresponding to factors of 1.6, 1.8 and 2.0) and accordingly independent of temperature. The forward dissociative attachment of electrons has k 1 such that its activation energy is the exothermicity of the reaction. The cross-section (nor2) for this direction is large and the same for each halogen, being 1.5 x 10 -18 m 2 . From the reaction X+ e - + M->X - + M not apparently occurring (M being any molecule acting as a chaperon) in flames, we conclude that its rate coefficient is less than 3 x 10 -29 ml 2 molecule -2 s -1 for these three halogens at temperatures of around 2000 K.

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The kinetics and mechanism of the reactions between carbon monoxide and ruthenium(II) chlorides in solution

Canadian Journal of Chemistry ◽

10.1139/v70-608 ◽

1970 ◽

Vol 48 (23) ◽

pp. 3613-3618 ◽

Cited By ~ 3

Author(s):

B. C. Hui ◽

B. R. James

Keyword(s):

Carbon Monoxide ◽

Molecular Nitrogen ◽

Second Order ◽

Kinetics And Mechanism ◽

Gas Uptake ◽

First Order ◽

Kinetics Of Formation ◽

Low Pressures ◽

Kinetics Of ◽

Hcl Solution

The kinetics of formation of mono- and dicarbonyl complexes in two successive stages by direct carbonylation of ruthenium(II) chlorides in dimethylacetamide solution have been studied at 65–80° and up to 1 atm CO by gas uptake techniques. Both stages are first order in ruthenium. Formation of the monocarbonyl is independent of CO pressure; dicarbonyl formation is first order in CO at low pressures with the order decreasing towards zero with increasing pressure, and shows an inverse chloride dependence from 0.1–2.0 M added chloride. For both stages, the data are consistent with a mechanism involving predissociation. A similar mechanism is suggested for the corresponding reactions in 3 M HCl solution which had been studied earlier and which showed overall second-order kinetics.Discussion on the related formation of molecular nitrogen complexes of ruthenium(II) is presented.

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The mechanism of the acetaldehyde pyrolysis

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1967.0073 ◽

1967 ◽

Vol 297 (1450) ◽

pp. 365-375 ◽

Cited By ~ 34

Keyword(s):

Carbon Monoxide ◽

Main Chain ◽

Small Contribution ◽

Methyl Radicals ◽

Additional Source ◽

Elementary Processes ◽

Order Coefficient ◽

Kinetics Of Formation ◽

Low Pressures ◽

Kinetics Of

Previous work on the acetaldehyde pyrolysis is shown to be vitiated by the presence, in the acetaldehyde, of impurities, mainly ethanol and crotonaldehyde. The reaction has been reinvestigated with the use of acetaldehyde, prepared from paraldehyde, which is free from these and other impurities. On the basis of a study of the kinetics of formation of the major products (methane and carbon monoxide) and of a number of minor products (hydrogen, acetone, propionaldehyde, ethane and ethylene) a reaction mechanism is proposed. This includes all of the reactions in the original Rice-Herzfeld scheme, together with a number of other elementary processes, in particular CH 3 + CH 3 CHO → CH 4 + CH 2 CHO. The decomposition of the radical CH 2 CHO into CH 2 CO and H provides an additional source of hydrogen, the rate of production of which is therefore not a measure of the rate of the initiation process. Acetone is believed to arise mainly by the reaction CH 3 + CH 3 CHO → CH 3 COCH 3 + H, and only to a negligible extent by the combination of CH 3 and CH 3 CO. The main chain-ending step is concluded to be CH 3 + CH 3 → C 2 H 6 , with a small contribution from CH 3 + CH 2 CHO → CH 3 CH 2 CHO. The work provides further evidence for the falling off, at low pressures, of the second order coefficient for the combination of methyl radicals. Rate constants for various elementary processes are deduced from the rates of formation of the various products, and are shown to be consistent with values obtained directly.

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Kinetics of cyclization of S-ethoxycarbonylmethylisothiouronium chloride to 2-imino-4-thiazolidone

Collection of Czechoslovak Chemical Communications ◽

10.1135/cccc19790912 ◽

1979 ◽

Vol 44 (3) ◽

pp. 912-917 ◽

Cited By ~ 1

Author(s):

Vladimír Macháček ◽

Said A. El-bahai ◽

Vojeslav Štěrba

Keyword(s):

Hydrochloric Acid ◽

Dilute Hydrochloric Acid ◽

Base Catalysis ◽

General Base ◽

Rate Limiting Step ◽

Limiting Step ◽

Kinetics Of Formation ◽

Acid Catalyzed ◽

Rate Limiting ◽

Kinetics Of

Kinetics of formation of 2-imino-4-thiazolidone from S-ethoxycarbonylmethylisothiouronium chloride has been studied in aqueous buffers and dilute hydrochloric acid. The reaction is subject to general base catalysis, the β value being 0.65. Its rate limiting step consists in acid-catalyzed splitting off of ethoxide ion from dipolar tetrahedral intermediate. At pH < 2 formation of this intermediate becomes rate-limiting; rate constant of its formation is 2 . 104 s-1.

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Cyclization and acid-catalyzed hydrolysis of O-benzoylbenzamidoximes

Collection of Czechoslovak Chemical Communications ◽

10.1135/cccc19862786 ◽

1986 ◽

Vol 51 (12) ◽

pp. 2786-2797

Author(s):

František Grambal ◽

Jan Lasovský

Keyword(s):

Reaction Rate ◽

Kinetic Isotope ◽

Acid Base Equilibrium ◽

Mineral Acids ◽

Kinetics Of Formation ◽

Acid Catalyzed ◽

Ph Scale ◽

Kinetics Of ◽

Hydrolysis Of ◽

Derivatives Of

Kinetics of formation of 1,2,4-oxadiazoles from 24 substitution derivatives of O-benzoylbenzamidoxime have been studied in sulphuric acid and aqueous ethanol media. It has been found that this medium requires introduction of the Hammett H0 function instead of the pH scale beginning as low as from 0.1% solutions of mineral acids. Effects of the acid concentration, ionic strength, and temperature on the reaction rate and on the kinetic isotope effect have been followed. From these dependences and from polar effects of substituents it was concluded that along with the cyclization to 1,2,4-oxadiazoles there proceeds hydrolysis to benzamidoxime and benzoic acid. The reaction is thermodynamically controlled by the acid-base equilibrium of the O-benzylated benzamidoximes.

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