A unified theory of the stability of benzenoid hydrocarbons

In 1973, Hall noticed that the total -electron energy E of isomeric Ž . benzenoid hydrocarbons is a linear function of the number of Kekule structures K . Śince then, this remarkable rule has been confirmed on a plethora of examples. Twenty Ž . years later, it was discovered that for large benzenoid

A method for the estimation of E,,, the number of benzenoid systems with h hexagons, is presented. B,, is predicted to lie between 3.200x lo6 and 3.202x 106. This is a significant improvement on the earlier result which located BI1 between 3.080~ lo6 and 3.300x 106.

Vuiation of concentration ofCeH6, C6D6, CiHsCH3, and o-CgH+(CH& in metbylcyclohexane ~~e.s a de-ae&ce in the ratio of phosphorescence to fluorescence yields and also the phosphorescence decay times at 77 K. The detection of delayed fluorescence shows that triplet-triplet annihilation czn explain the

There are series of C&H, formulas for benzenoid hydrocarbons which correspond to equal numbers of isomers. General expressions (in two schemes) are reported for these formulas. The numbers of isomers for these constant-isomer series are treated by a combination of mathematical analysis and computer-