Oligothiophenes incorporating MM quadruple bonds have been prepared from the reactions between Mo2(TiPB)4 (TiPB ؍ 2,4,6-triisopropyl benzoate) and 3,4-dihexyl-2,2-:5,2؆-terthiophene-5,5؆-dicarboxylic acid. The oligomers of empirical formula Mo2(TiPB)2(O2C(Th)-C4(n-hexyl)2S-(Th)CO2) are soluble in THF and form thin films with spin-coating (Th ؍ thiophene). The reactions between Mo2(TiPB)4 and 2-thienylcarboxylic acid (Th-H), 2,2-bithiophene-5-carboxylic acid (BTh-H), and (2,2:5,2؆-terthiophene)-5-carboxylic acid (TTh-H) yield compounds of formula trans-Mo2(TiPB)2L2, where L ؍ Th, BTh, and TTh (the corresponding thienylcarboxylate), and these compounds are considered as models for the aforementioned oligomers. In all cases, the thienyl groups are substituted or coupled at the 2,5 positions. Based on the x-ray analysis, the molecular structure of trans-Mo2(TiPB)2(BTh)2 reveals an extended L-M2␦-L conjugation. Calculations of the electronic structures on model compounds, in which the TiPB are substituted by formate ligands, reveal that the HOMO is mainly attributed to the M2␦ orbital, which is stabilized by back-bonding to one of the thienylcarboxylate * combinations, and the LUMO is an in-phase combination of the thienylcarboxylate * orbitals. The compounds and the oligomers are intensely colored due to M2␦-thienyl carboxylate * charge transfer transitions that fall in the visible region of the spectrum. For the molybdenum complexes and their oligomers, the photophysical properties have been studied by steady-state absorption spectroscopy and emission spectroscopy, together with time-resolved emission and transient absorption for the determination of relaxation dynamics. Remarkably, THF solutions the molybdenum complexes show room-temperature dual emission, fluorescence and phosphorescence, originating mainly from 1 MLCT and 3 MM(␦␦*) states, respectively. With increasing number of thienyl rings from 1 to 3, the observed lifetimes of the 1 MLCT state increase from 4 to 12 ps, while the phosphorescence lifetimes are Ϸ80 s. The oligomers show similar photophysical properties as the corresponding monomers in THF but have notably longer-lived triplet states, Ϸ200 s in thin films. These results, when compared with metallated oligothiophenes of the later transition elements, reveal that M 2␦-thienyl conjugation leads to a very small energy gap between the 1 MLCT and 3 MLCT states of <0.6 eV.photophysics ͉ dual emission B ecause of their potential applications in optoelectronic and magnetic devices, conjugated organic polymers have received much attention (1-3), and oligothiophenes, which constitute one important subclass of these materials, have been found to show excellent hole transport properties (3-7). We have been interested for some time in incorporating MM quadruple bonds into these oligomers by use of the carboxylate tether (8-10), such that the M 2 ␦ electrons can be brought into conjugation with an extended -framework of the thiophene moiety. As shown in Scheme 1, the out-of-phase combination of the carbo...
