The dominant impact of extrinsic electronic disorder was observed in α-sexithiophene (α-6T) films grown on C60/Au(111) substrates by scanning tunneling microscopy and spectroscopy measurements. Sexithiophene molecules adopt an upright orientation with a structure that reflects both bulklike α-6T packing and C60 substrate templating effects. Apparent height variations in these films are assigned as molecular sliding defects but are observed to have negligible impact on the energy of the highest occupied molecular orbital. This orbital energy varies more significantly in response to random changes in probe tip, implying that the dominant origin of electronic disorder in two-dimensional organic crystals can be extrinsic to the film.

Topics
Electronic transport, Crystalline solids, Dielectric materials, Scanning tunneling microscopy, Scanning tunneling spectroscopy, Fullerenes, Supramolecular chemistry, Intermolecular forces, Charge transport, Charged impurities
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2014
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