Journal of the American Chemical Society, Vol.128, No.10, 3291-3302, 2006
Reactive carbon-chain molecules: Synthesis of 1-diazo-2,4-pentadiyne and spectroscopic characterization of triplet pentadiynylidene (H-C=C-C-C=C-H)
1-Diazo-2,4-pentadiyne (6a), along with both monodeuterio isotopomers; 6b and 6c, has been synthesized via a route that proceeds through diacetylene, 2,4-pentadiynal, and 2,4-pentadiynal tosylhydrazone. Photolysis of diazo compounds 6a-c (lambda > 444 nm; Ar or N-2, 10 K) generates triplet carbenes HC5H (1) and HC5D (1-d), which have been characterized by IR, EPR, and UV/vis spectroscopy. Although many resonance structures contribute to the resonance hybrid for this highly unsaturated carbon-chain molecule, experiment and theory reveal that the structure is best depicted in terms of the dominant resonance contributor of penta-1,4-diyn-3-ylidene (diethynylcarbene, H-C equivalent to C-C-C equivalent to C-H). Theory predicts an axially symmetric (D-h) structure and a triplet electronic ground state for 1 (CCSD(T)/ANO). Experimental IR frequencies and isotope shifts are in good agreement with computed values. The triplet EPR spectrum of 1 (vertical bar D/hc vertical bar = 0.6157 cm(-1), vertical bar E/hc vertical bar = 0.0006 cm(-1)) is consistent with an axially symmetric structure, and the Curie law behavior confirms that the triplet state is the ground state. The electronic absorption spectrum of 1 exhibits a weak transition near 400 nm with extensive vibronic coupling. Chemical trapping of triplet HC5H (1) in an O-2-cloped matrix affords the carbonyl oxide 16 derived exclusively from attack at the central carbon.