PHYS 501 |
| Single Walled Carbon Nanotubes (SWNT) are important materials for nanotechnology devices and sensors. Future optoelectronic devices can be made from assemblies of diverse nanostructured materials and SWNTs, providing enhanced functionality. Ruthenium complexes have very strong absorbance in the visible spectrum. SWNTs have exceptional electron accepting and charge transfer properties. We have shown specific binding of these complexes with the end of SWNTs. Properties of these supramolecular nano-assemblies are being investigated to develop applications like sensors and photovoltaic cells. Photon enhanced aggregation properties of SWNT due to these ruthenium complexes are demonstrated. These organometalic based molecular adsorbates onto the nanotubes affect the field effect transistor response of SWNTs. Ruthenium centered phenanthroline complexes exhibit a strong metal to ligand charge transfer. We believe that the nanotube quenches charge from the ligand after the complex has been optically excited. This results in optically altering the carrier density, and therefore the transport properties of the nanotubes. We believe this is due to charge transfer from the metal center through the ligand and finally onto the nanotubes. The devices have been fabricated using e-beam and conventional lithography. Photon induced affects on the charge transport are shown. These devices were imaged using atomic force microscopy, and scanning electron microscopy. Spectroscopic analyses of these devices are also shown. Advancements towards realizing real-time optoelectronic sensors and nano devices are demonstrated. |
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PHYS Poster Session - Nanostructured Materials and Nanophotonics
7:30 PM-10:00 PM, Wednesday, April 9, 2008 Morial Convention Center -- Hall A, Poster
Sci-Mix
Division of Physical Chemistry |