Oxidative Coupling Of 2‐Alkyl‐6,6‐dimethylpentafulvenyl Anions

Chai

Schwarz

et al. 1997

Helvetica Chimica Acta

Self Cite

New Pathways to Precursors of PentalenePentalene dimers 2 and 3 are easily available in moderate yields by CuCI,-induced oxidative coupling of dilithium-pentalenediide (5) (Scheme f). On the other hand, NBS bromination of 1,5-dihydropentaIene (4) or of 1.2-dihydropentalene (8) gives unstable 1 h o m o -I ,2-dihydropentalene (9), while subsequent in-siru elimination with Et,N exclusively gives syn-cis-pentalene dimer 2 in moderdle yields (Scheme 3). NMR-Spectroscopic evidence for compounds 2,3, and 9 is presented, and mechanistic alternatives for the formation of pentalene dimers 2 and 3 are discussed. 1.Einleitung. -Pentalen (1)2)3) hat sowohl die synthetischen als auch die theoretischen organischen Chemiker seit mehr als vier Jahrzehnten fasziniert. Trotz zahlreicher Syntheseversuche konnte jedoch der Grundkorper 1 bisher spektroskopisch nicht charakterisiert werden, und alle bis heute isolierten substituierten Pentalene waren entweder sterisch oder elektronisch stabilisiert. Hexaphenylpentalen war das erste einfache Pentalen, welches 1962 durch Le Gofjrsynthetisiert wurde [4]; spater konnten die elektronisch stabilisierten Pentalene 1,3-Bis(dimethylamino)pentalen [5] und 1,4-Diamino-3,6-dime-

unclassified

Neue Wege zu Pentalen‐Vorstufen

Chai

Schwarz

et al. 1997

Helvetica Chimica Acta

Self Cite

ChemInform Abstract: Coupling Reactions. Part 11. Oxidative Coupling of 2‐Alkyl‐6,6‐ dimethylpentafulvenyl Anions.

Neuenschwander

1994

ChemInform

Oxidative Coupling of 6,6‐Dimethylpentafulvenyl Anion

Neuenschwander

Huber

1993

Helvetica Chimica Acta

Self Cite

Oxidative treatment of anion 11 (obtained by deprotonation of 6,6‐dimethylpentafulvene 10, Scheme 3) with CuCl2 gives a very complex mixture of coupling products 13 (18%), 14 (16%), 15 (36%), 16 (5%), and 17 (6%) (Scheme 4 and Table 2). These results show that the reactive intermediate obtained by oxidation of 11 (which is believed to be the fulvenyl radical 12) has several reactive sites. According to the experiments, reactivity is decreasing in the series C(7) > C(2)/C(3) > C(5) > C(1)/C(4) (Table 2), while simple frontier‐orbital considerations would suggest the sequence C(7) > C(5) > C(2)/C(3) > C(1)/C(4). The results suggest that SOMO‐SOMO interaction of the approaching fulvenyl radicals 12 is the central effect governing regioselectivity and product distribution, while Coulomb and steric interactions are secondary effects (Table 4).