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41	Thermodynamic properties of multicomponent mixtures from the solution of groups approach to direct correlation function solution theory Telotte, John Charles, January 1985 (has links) Thesis (Ph. D.)--University of Florida, 1985. / Description based on print version record. Typescript. Vita. Includes bibliographical references (leaves 163-166).
42	Certain aspects of the thermal decomposition of chromium trioxide ... Coull, James, January 1933 (has links) Thesis (Ph. D.)--Columbia University, 1934. / Vita. Bibliography: p. 31.
43	Thermochemical measurements of slow reactions with a new isothermal calorimeter Coon, Ernest D. January 1932 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1932. / Typescript. With this is bound: An isothermal calorimeter for slow reactions / by E.D. Coon and Farrington Daniels. Reprinted from Journal of physical chemistry, vol. XXXVII, no. 1 (Jan. 1933), 12 p. Includes bibliographical references.
44	The decomposition of organic compounds at high temperatures and pressures ... Herndon, Lee Roy, January 1928 (has links) Thesis (Ph. D.)--Johns Hopkins University, 1928. / Biography. Chemistry, Organic. Thermochemistry.
45	The thermal decomposition of metal alkyls in hydrogenethylene mixtures ... Jones, William Henry, January 1930 (has links) Thesis (Ph. D.)--Princeton University, 1930.
46	A study of the heats of dilution of certain aqueous salt solutions Stearn, Allen E. January 1919 (has links) Thesis (Ph. D.)--University of Illinois, 1919. / Biography. Solution (Chemistry) Thermochemistry.
47	Studies at high temperatures ... Sthapitanonda, Prasom, January 1955 (has links) Thesis (Ph. D.)--University of Wisconsin--Madison, 1955. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 131-142). High temperatures. Thermochemistry.
48	Ab initio investigation of the thermochemistry, spectroscopy and dynamics of reactions between mercury and reactive halogen species Shepler, Benjamin C., January 2006 (has links) (PDF) Thesis (Ph. D.)--Washington State University, August 2006. / Includes bibliographical references.
49	Drift tube ion mobility measurements for thermochemistry, kinetics and polymerization of cluster ions Mabrouki, Ridha Ben Mohsen. January 1900 (has links) Thesis (Ph.D.)--Virginia Commonwealth University, 2007. / Title from title-page of electronic thesis. Prepared for: Dept. of Chemistry. Bibliography: leaves 134-140.
50	The thermal decomposition of benzyl iodide Gow, John Stobie January 1961 (has links) The results of the work, described in this thesis, may be summarized as follows:- 1) The gas phase pyrolysis of benzyl iodide, either alone or in the presence of added free iodine, proceeds via the following mechanism BzI ⟷Ke Bz + I I + I ⟷ I 2 Bz + Bz ⟶ k2 Bz-Bz An analysis of the data has been carried out where reactions (a) and (b) are presumed to reach equilibrium and reaction (c) is rate determining. Over a temperature range of 516°K, carried out using both static (516-557°K) and flow (611-702°K) systems with benzyl iodide partial pressures from. 03 mm. to 9.0 mm., the logarithm of 2 k2Ke2 plotted against 1/(T°K) gave a straight line. The slope of this Line on the above mechanism is equal to (2 △h+E)/2.3R (where △ = change in heat content associated with the equilibrium BzI ⟷Bz + I and E = the activation energy of the reaction Bz + Bz ⟶ Bz-Bz) and (2 △H + E) was found to be 84 K cal./mol. On the assumption that E = O, this is equivalent to a benzyl iodide bond strength of 42 K cal./mol. This experimentally derived bond strength must be reduced by 1 K cal./mol. for every 2 K cal./mol. Of energy of activation required by the recombination of tow benzyl radicals. A review of the literature, on free radical recombination energies, suggests that for benzyl radicals it is not likely to exceed 4-5 L cal./mol. And therefore the present investigation leads to a value of 40-42 K cal./mol. for the strength of the carbon-iodine bond in benzyl iodide. 2) It has been shown that, in the presence of excess hydrogen iodide as a radical acceptor, benzyl iodide decomposes according to the following mechanism – (a) BzI ⟶ Bz + I (b) I + I ⟷I2 (d) Bz + HI ⟶ Bz-H + I (e) I + BzI ⟶ Bz + I2 In this scheme, the rate determining process is the dissociation process in (a) since, with sufficient HI present, reaction (d) prevents an equilibrium concentration of benzyl radicals being built up. It has been shown to be possible to obtain conditions where the rate of iodine formation is independent of HI concentrations. Using such conditions, reaction epsilon was shown to be a very significant contributor to the total rate. Moreover, the elimination of the back reaction in (a) produced a large increase in decomposition rate, so much so that the range of temperature used in this section of the work was over 100oC below that for the previous section. The energy of activation of the reaction (e); has been determined as 4.1 K cal./mol. (This value was calculated from results covering the temperature range 505 to 585°K). Using Perlman and Rollefson's(78) data on the dissociation of molecular iodine, this activation energy of 4.1 K cal./mol. is equivalent to a benzyl iodide bond strength of 40.6 K cal./mol. This value is in good agreement with that obtained from the pyrolysis work in the absence of a radical acceptor. The initial dissociation reaction (Bzl ⟶ Bz + I) has been found to be between first and second order at the partial pressures of benzyl iodide used (0.02 mm. - 0.13 mm.) and this is attributed to the normal Hinshelwood-Lindemann effect for unimolecular reactions. An approximate value of 0.35 sec.−1 for the high pressure limiting rate constant at 585°K has been deduced. This corresponds to an Arrhenius factor for the decomposition of 1014.6 sec.−1, if the benzyl iodide bond strength is assumed to be 40.6 K cal./mol. 3) At the very lowest partial pressures used (~0.02 mm.), the initial dissociation reaction approaches second order behaviour and the temperature dependence of assumed second order rate constants leads to an activation energy of 40 K cal./mol. for the decomposition. The corresponding pre-exponential factor is 10 20.4, which is of the order of magnitude to be expected for a reaction of this type. The data, in this low pressure region, are, however, insufficient to establish that the reaction in accurately second order at these pressure. 4) If the bond strength of benzyl iodide is taken as 41 K cal./mol., as determined in this present investigation, a value may be calculated for the heat of formation of the benzyl radical. Using 27.2 K cal./mol. for the heat of benzyl iodide, as suggested by skinner(63), a value of 43 K cal./mol. is obtained for △Hf (benzyl). This is in close agreement with the values of 45.3 K cal./mol. and 44.8 cal./mol., obtained in this department by Alexander(58) and Davidson(59) respectively - their values were derived their determinations of the bond strength of the central carbon-carbon bond in dibenzyl. The present value of 43 L cal./mol. is also in accord with the 44.9 K cal./mol., deduced from Benson and buss(47) determination of the toluene bond strength as 84 K cal./mol. The more commonly quoted toluene bond strength of 77.5 K cal./mol., obtained by Szwarc(48) leads to a △Hf (Benzyl) of only 37.4 K cal./mol. and would, therefore, seem to be too low. QD511.G7 ; Thermochemistry

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