Cyclohexanes interaction

In photoirradiated solid cyclohexane (freezing point 6.5°C), much higher fluorescence quantum yields and longer fluorescence lifetimes were observed than in the liquid phase [89]. In solid Ar matrices, the fluorescence characteristics, energy dependence of the lifetime and intensity, were found to be very similar to these characteristics in the gas phase. This points to the importance of cyclohexane-cyclohexane interactions to determine the excited-state characteristics in the liquid phase [76]. 

Origin of 1,3-diaxial cyclohexane interactions in methylcyclohexane. The steric strain between an axial methyl group and an axial hydrogen atom three carbons away is identical to the steric strain in gauche butane. (Note that the -CHj group in methylcyclohexane is displaced slightly away from a true axial position to minimize (see onTputer ald... 

A modified boat conformation of cyclohexane, known as the twist boat (Fig. 1.8), or skew boat, has been suggested to minimize torsional and nonbounded interactions. This particular conformation is estimated to be about 1.5 kcal moE (6 kJ moE ) lower in energy than the boat form at room temperature. 

Polyisobutylene is readily soluble in nonpolar Hquids. The polymer—solvent interaction parameter Xis a. good indication of solubiHty. Values of 0.5 or less for a polymer—solvent system indicate good solubiHty values above 0.5 indicate poor solubiHty. Values of X foi several solvents are shown in Table 2 (78). The solution properties of polyisobutylene, butyl mbber, and halogenated butyl mbber are very similar. Cyclohexane is an exceUent solvent, benzene a moderate solvent, and dioxane a nonsolvent for polyisobutylene polymers. 

When two or more substituents are present on a cyclohexane ring, the interactions between the substituents must be included in the analysis. The dimethylcyclohexanes provide an example in which a straightforward interpretation is in complete agreement with the experimental data. For 1,2-, 1,3-, and 1,4-dimethylcyclohexane, the free-energy change of the equilibrium for the cis trans isomerization is given below. ... 

The decalin (bicyclo[4.4.0]decane) ring system provides another important system for study of conformational effects in cyclohexane rings. Equilibration of the cis and trans isomers reveals that the trans isomer is favored by about 2.8 kcal/mol. Note that this represents a change in configuration, not conformation. The energy difference can be analyzed by noting that the cis isomer has three more gauche butane interactions that are... 

Most other studies have indicated considerably more complex behavior. The rate data for reaction of 3-methyl-l-phenylbutanone with 5-butyllithium or n-butyllithium in cyclohexane can be fit to a mechanism involving product formation both through a complex of the ketone with alkyllithium aggregate and by reaction with dissociated alkyllithium. Evidence for the initial formation of a complex can be observed in the form of a shift in the carbonyl absorption band in the IR spectrum. Complex formation presumably involves a Lewis acid-Lewis base interaction between the carbonyl oxygen and lithium ions in the alkyllithium cluster. 

According to this concept, the aldol condensation normally occurs through a chairlike transition state. It is further assumed that the stmcture of this transition state is sufficiently similar to that of chair cyclohexane to allow the conformational concepts developed for cyclohexane derivatives to be applied. Thus, in the example above, the reacting aldehyde is shown with R rather than H in the equatorial-like position. The differences in stability of the various transition states, and therefore the product ratios, are governed by the steric interactions between substituents. 

The spectra of an organic compound in various solvents differ only in small detail so long as no serious interaction takes place between solute and solvent. Thus the spectrum of a substance in an aprotic solvent (e.g. cyclohexane) should be almost the same as that in water. When addition of water occurs across a C=N bond, the spectrum of the hydrate in water can be vastly different from the spectrum of the anhydrous substance in cyclohexane, and this test has been used on several occasions determine whether or not a neutral species... 

Although the addition of hydrazine and its derivatives to acetylenic ketones has been studied in considerable detail, their interaction with hydrazones and mono-alkylhydrazones is less well known. Yandovskii and Klindukhova (74ZOR730) have studied the reaction between hydrazones and alkylhydrazones of aliphatic ketones with dipropynylketones and showed that hydrazones of acetone, methyl-ethylketone, and cyclohexane easily add to one of the triple bonds of dipropynylketone to form 4-methyl-1,1,3-trialkyl-2,3-diaza-l,4-nonadien-7-yn-6-ones (yields... 

Bamford and coworkers [19] have shown that a prolonged aftereffect can be obtained with Mn-carbonyl in the presence of certain additives, notably cyclohexane and acetylacetone (S), It was suggested that the photochemical reaction between Mn2(CO)io and (S) produces the active species (Z), which generates free radicals by interaction with halide and Z probably formed from Mn (CO)6 species ... 

Monosubstituted cyclohexanes are more stable with their substituent in an equatorial position, but the situation in disubstituted cyclohexanes is more complex because the steric effects of both substituents must be taken into account. All steric interactions in both possible chair conformations must be analyzed before deciding which conformation is favored. 

Interactive to learn to draw and assess the stability of substituted cyclohexanes. 

Thomson fOV Click Organic Interactive to learn to recognize the most stable conformations of cyclohexanes following ring-flips. 

Thomson NOV Click Organic Interactive to use an online palette to draw and interconvert cyclohexane structures. 

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