par Crispin, Xavier;Cornil, Jérôme 
;Friedlein, Rainer;Okudaira, Koji Kamiya;Lemaur, Vincent;Crispin, Annica;Kestemont, Gaël ;Lehmann, Matthias ;Fahlman, Mats;Lazzaroni, Roberto;Geerts, Yves ;Wendin, G.;Ueno, Nobuo;Brédas, Jean-Luc;Salaneck, William R
Référence Journal of the American Chemical Society, 126, 38, page (11889-11899)
Publication Publié, 2004
;Friedlein, Rainer;Okudaira, Koji Kamiya;Lemaur, Vincent;Crispin, Annica;Kestemont, Gaël ;Lehmann, Matthias ;Fahlman, Mats;Lazzaroni, Roberto;Geerts, Yves ;Wendin, G.;Ueno, Nobuo;Brédas, Jean-Luc;Salaneck, William RRéférence Journal of the American Chemical Society, 126, 38, page (11889-11899)
Publication Publié, 2004
Article révisé par les pairs
| Résumé : | Discotic liquid crystals emerge as very attractive materials for organic-based (opto)electronics as they allow efficient charge and energy transport along self-organized molecular columns. Here, angle-resolved photoelectron spectroscopy (ARUPS) is used to investigate the electronic structure and supramolecular organization of the discotic molecule, hexakis(hexylthio)diquinoxalino[2,3-a:2',3'-c]phenazine, deposited on graphite. The ARUPS data reveal significant changes in the electronic properties when going from disordered to columnar phases, the main feature being a decrease in ionization potential by 1.8 eV following the appearance of new electronic states at low binding energy. This evolution is rationalized by quantum-chemical calculations performed on model stacks containing from two to six molecules, which illustrate the formation of a quasi-band structure with Bloch-like orbitals delocalized over several molecules in the column. The ARUPS data also point to an energy dispersion of the upper pi-bands in the columns by some 1.1 eV, therefore highlighting the strongly delocalized nature of the pi-electrons along the discotic stacks. |
