Isodesmic reactions compounds

Isodesmic reactions may be studied in themselves. For example, energy differences may be compared between the reactants and products in order to predict AH. In addition, isodesmic reactions may be used to predict the heats of formation for compounds of interest by predicting AH for the reaction and then computing the desired heat of formation by removing the known heats of formation for the other compounds from this quantity. We will look at an example of each type in this section. 

Isodesmic reactions 2 and 3 were calculated as a measure of the relative ease of formation of the aza-epoxides, in order to obtain some insight as to the effect of nitrogen atom on metabolic activation of aza-PAHs. It was presumed that formation of the epoxides is not as relevant as carbocation formation in determining the relative reactivities of Phe, BhQ and BfQ, because almost no energy differences were observed for the isodesmic reactions involving these compounds. 

When considering the stability of spin-delocalized radicals the use of isodesmic reaction Eq. 1 presents one further problem, which can be illustrated using the 1-methyl allyl radical 24. The description of this radical through resonance structures 24a and 24b indicates that 24 may formally be considered to either be a methyl-substituted allyl radical or a methylvinyl-substituted methyl radical. While this discussion is rather pointless for a delocalized, resonance-stabilized radical such as 24, there are indeed two options for the localized closed shell reference compound. When selecting 1-butene (25) as the closed shell parent, C - H abstraction at the C3 position leads to 24 with a radical stabilization energy of - 91.3 kj/mol, while C - H abstraction from the Cl position of trans-2-butene (26) generates the same radical with a RSE value of - 79.5 kj/mol (Scheme 6). The difference between these two values (12 kj/mol) reflects nothing else but the stability difference of the two parents 25 and 26. 

It is worth mentioning at this point that the formation of a a -phosphorus from a -phosphorus resulted in a-aromatic compounds in the case of the l//-phosphirenium cation as well. Disubstitution at the phosphorus in l//-phosphirenium cation (5) resulted in the preservation of aromaticity with proper substituents (fluorine) in 36, as a result of the interaction with PF2 a -orbitals,as indicated by isodesmic reactions. A similar phenomenon has been observed also for 1,1-difluorocyclopropene, 1,1-bissilylcyclopentadiene, and 1,1-bisstannylcyclopen-tadiene. In the latter case, the phenomenon has been called hyperconjugate aromaticity . The effect of... 

The MNDO calculations on sila-, germa-, and stannacyclopentadienyli-denes have shown that whereas for cyclopentadienylidene (272) the energies of the antiaromatic 47t- and the aromatic 6ir-electron structures are close in value (89UK1067), in the (273)-(275) series the 67r-electron structures are quite noticeably destabilized (Table XXIII). Unlike (272), the electronic ground state of compounds (273)—(275) correspond to minima on the PES. These results point to the diminished role of antiaromatic destabilization in the 47r-electron structure (273)—(275), as opposed to (272). It should therefore be expected that these molecules would be more stable than (272). This has indeed been confirmed by our calculation on the heats of the isodesmic reaction (85) (Table XXIII). 

As will be discussed in Chapter 13, calculated energies of one particular class of isodesmic reactions, so-called bond separation reactions, may be combined with experimental or high-quality calculated thermochemical data in order to lead directly to accurate heats of formation. These in turn can be used in whatever types of thermochemical comparisons are of interest. We start our assessment of isodesmic processes with bond separation reactions. Following this, we consider description of bond dissociation energies, hydrogenation energies and acid and base strengths in terms of isodesmic processes, that is, not as absolute quantities but expressed relative to standard compounds. 

Another important type of isodesmic reaction compares acid (or base) strength to that of a closely-related standard compound, for example, the basicity of trimethylamine relative to that of ammonia as a standard. This differs fundamentally from absolute acid (or base) strength comparisons, which are heterolytic bond dissociations and which significantly alter overall bonding. ... 

These compounds, (2) and (3), are of theoretical interest, since they have cyclic 7r-orbital systems, and ab initio MO calculations have been performed to estimate what degree of stabilization may result. This was done by calculating the AE for their formation by an isodesmic reaction with a hypothetical cyclobutanone enol ion (19a,b), which also has a four-membered ring with an allylic system conjugated to an oxygen atom. 

Evidence for aromatic Ji-delocalisation in Si(N N ) (2) included (i) the greatly enhanced (Raman) C=C stretching mode in 2 over non-aromatic reference compounds and comparisons of (ii) the enthalpies (2 > 4) of the isodesmic reactions for 2(or 4) -f SiH4... 

To explore this possibility further, quantum chemical calculations were carried out for the isodesmic reactions of the model compounds 66 and 67 with dihydrogen to give the corresponding dihydrides (Scheme 17). These calculations showed that the reaction of 66 with H2 is about 14 kcalmol-1 less exothermic than that of 67. This difference may reflect aromatic resonance energy in the unsaturated molecule 66, reducing the enthalpy of the hydrogenation reaction. 

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