Tetramethylheptalenes and Their Tricarbonylchromium Complexes: Synthesis,Structures, and Thermal Rearrangements

The thermal 4 : 1 equilibrium mixture of 1,3,5,6- and 1,3,5,10-tetramethylheptalene ( 13a and 13b , resp.) has been prepared, starting from the thermal equilibrium mixture of dimethyl 6,8,10-trimethylheptalene-1,2- and -4,5-dicarboxylate ( 6a and 6b , resp.; cf. Scheme 5). These heptalenes undergo double-bond shifts (DBS) even at ambient temperature. Treatment of the mixture 13a / 13b 4 : 1 with Cr(CO)₃(NH₃)₃] in boiling 1,2-dimethoxyethane resulted in the formation of all four possible mononuclear Cr(CO)₃ complexes 19a – 19d of 13a and 13b , as well as two binuclear Cr(CO)₃ complexes 20a and 20b , respectively, in a total yield of 87% (cf. Scheme 7). The mixture of complexes was separated by column chromatography, followed by preparative HPLC (cf. Fig. 2). The structures of all complexes were established by X-ray crystal-structure analyses (complex 19b and 20b ; cf. Figs. 6 – 8) and extensive ¹H-NMR measurements (cf. Table 3). In 20b , the two Cr(CO)₃ groups are linked in a `syn'-mode to the highly twisted heptalene π-skeleton. The correspondence of the <sup>1</sup>H-NMR data of 20a with that of 20b indicates that the two Cr(CO)<sub>3</sub> groups in 20a also have a `syn'-arrangement. The thermal behavior of the mononuclear complexes 19a – 19d has been studied at 85° in hexafluorobenzene (HFB). At this temperature, all four complexes undergo rearrangement to the same thermal equilibrium mixture (cf. Table 8). The rates for the thermal equilibration of each complex have been determined by ¹H-NMR measurements (cf. Figs. 9 – 12) and analyzed by seven different kinetic schemes (Chapt. 2). The equilibration rates are in agreement with two different haptotropic rearrangements that take place, namely intra- and inter-ring shifts of the Cr(CO)₃ group, whereby both rearrangements are accompanied by DBS of the heptalene π-skeleton (cf. Scheme 9). All individual kinetic steps possess similar ΔG^≠ values in the range of 29 – 31 kcal?mol^?1 (cf. Table 8). The occurrence of inter-ring haptotropic migrations of Cr(CO)₃ groups has already been established for anellated aromatic systems (cf. Scheme 10); however, it is the first time that these rearrangements have been unequivocally demonstrated for Cr(CO)₃ complexes of non-planar bicyclic 4n]annulenes, such as heptalenes. The mechanism of migration may be similar to that proposed for aromatic systems (cf. Schemes 10 and 11).