Journal of the American Chemical Society, Vol.126, No.42, 13695-13702, 2004
Synthesis and properties of monodisperse oligofluorene-functionalized truxenes: Highly fluorescent star-shaped architectures
This paper describes the strategy toward novel monodisperse, well-defined, star-shaped oligofluorenes with a central truxene core and from monofluorene to quaterfluorene arms. Introduction of solubilizing n-hexyl groups at both fluorene and truxene moieties results in highly soluble, intrinsically two-dimensional nanosized macromolecules T1-T4. The radius for the largest oligomer of ca. 3.9 nm represents one of the largest known star-shaped conjugated systems. Cyclic voltammetry experiments reveal reversible or quasi-reversible oxidation and reduction processes (E-ox = +0.74 to 0.80 V, E-red = -2.66 to 2.80 eV vs Fc/Fc(+)), demonstrating excellent electrochemical stability toward both p- and n-doping, while the band gaps of the oligomers are quite high (E-g(CV) = 3.20-3.40 eV). Close band gaps of 3.05-3.29 eV have been estimated from the electron absorption spectra. These star-shaped macromolecules demonstrate good thermal stability (up to 400-420 degreesC) and improved glass transition temperatures with an increase in length of the oligofluorene arms (from T-g = 63 degreesC for T1 to 116 degreesC for T4) and show very efficient blue photoluminescence (lambda(PL) = 398-422 nm) in both solution (Phi(PL) = 70-86%) and solid state (PhiPL = 43-60%). Spectroelectrochernical experiments reveal that compounds T1-T4 are stable electrochromic systems which change their color reversibly from colorless in the neutral state (similar to340-400 nm) to colored (from red to purple color; similar to500-600 nm) in the oxidized state.