Heilweil, E.
, Johnson, J.
, Mosley, K.
, Lubet, P.
, Charles, W.
and Burkey, T.
(2011),
Engineering Organometallic Femtosecond Chemistry: Photochemistry and Dynamics of Ultrafast Chelation of Cyclopentadienylmanganese Tricarbonyl Derivatives with Pendant Benzenecarbonyl and Pyridinecarbonyl Groups, Organometallics
(Accessed April 25, 2024)
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Engineering Organometallic Femtosecond Chemistry: Photochemistry and Dynamics of Ultrafast Chelation of Cyclopentadienylmanganese Tricarbonyl Derivatives with Pendant Benzenecarbonyl and Pyridinecarbonyl Groups
Published
Author(s)
, Jermaine O. Johnson, Karen L. Mosley, Phillipe P. Lubet, Webster E. Charles, T J. Burkey
Abstract
A new method was developed to prepare three cyclopentadienyl manganese tricarbonyl derivatives 1, 4, and 5 with different side chains (Mn{ 5-C5H4CH2COR}(CO)3, R = 2- pyridyl 1, phenyl 4, and 4-pyridyl 5). Steady-state UV-vis, FTIR, and NMR studies in heptane show that chelates 2, 6, and 7 are formed, respectively, with the side-chain oxygen but decay on the minute timescale. A side chain chelate 3 with nitrogen is also observed in competition with 2. The rearrangement of the O-chelate 2 to the nitrogen chelate 3 is a unimolecular process (a non-dissociative linkage isomerization) that is faster than the decay observed for the O-chelate 6 (phenyl instead of a 2-pyridyl side chain), even in the presence of 0.1 M pyridine for the latter. Ultrafast chelation is observed with the side-chain oxygen following irradiation of 4 and 5 during timeresolved infrared (TRIR) studies in heptane. Ultrafast chelation is also observed for both side-chain nitrogen and oxygen following irradiation of 1. The lack of ultrafast solvent coordination following irradiation of 1 indicates that the formation of these chelates is a sub-picosecond process. A split in the degenerate stretching bands 4 and 5 in FTIR spectra suggests that there is a significant electronic communication between the side chain and the metal carbonyl groups. These results suggest that ultrafast chelation is favored by side-chain conformations that position a functional group near the metal center.Citation
Organometallics
Volume
30
Pub Type
Journals
Keywords
manganese tricarbonyls, molecular design, photoswitch, time-resolved infrared, ultrafast chelation
Citation
Created October 24, 2011, Updated January 27, 2020