Oxygen-Related Band Gap State in Single Crystal Rubrene
- 19 October 2006
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 97 (16) , 166601
- https://doi.org/10.1103/physrevlett.97.166601
Abstract
A molecular exciton signature is established and investigated under different ambient conditions in rubrene single crystals. An oxygen-related band gap state is found to form in the ambient atmosphere. This state acts as an acceptor center and assists in the fast dissociation of excitons, resulting in a higher dark and photoconductivity of oxidized rubrene. The band gap state produces a well-defined photoluminescence band at an energy 0.25 eV below the energy of the 0-0 molecular exciton transition. Two-photon excitation spectroscopy shows that the states are concentrated near the surface of naturally oxidized rubrene.Keywords
This publication has 17 references indexed in Scilit:
- Ultrafast carrier dynamics in pentacene, functionalized pentacene, tetracene, and rubrene single crystalsApplied Physics Letters, 2006
- Primary Photoexcitations and the Origin of the Photocurrent in Rubrene Single CrystalsPhysical Review Letters, 2006
- Determination of the interface trap density of rubrene single-crystal field-effect transistors and comparison to the bulk trap densityJournal of Applied Physics, 2006
- Hall Effect in the Accumulation Layers on the Surface of Organic SemiconductorsPhysical Review Letters, 2005
- Electronic transport properties of pentacene single crystals upon exposure to airApplied Physics Letters, 2005
- The effect of oxygen exposure on pentacene electronic structureThe European Physical Journal E, 2005
- Intrinsic Charge Transport on the Surface of Organic SemiconductorsPhysical Review Letters, 2004
- Amorphouslike Density of Gap States in Single-Crystal PentacenePhysical Review Letters, 2004
- Effect of impurities on the mobility of single crystal pentaceneApplied Physics Letters, 2004
- The Effect of Oxygen on the Photoconductivity of Anthracene. IIThe Journal of Chemical Physics, 1954