Benjamin Pound, Utah State University
Physical Sciences
Carbon Nanotube (CNT) Forests are vertically grown carbon nanotubes. They can be as tall as millimeters, with radii from less than one nanometer (single-walled) to tens of nanometers (multi-walled). Their high surface area to volume ratio provides a unique material system for biosensor applications. However, the CNT surface does not provide covalent bonding sites to many antibodies of interest. One approach is to attach linker molecules with aromatic rings via π-stacking to the CNT surface and activating the linker molecules to bind covalently to specific antibody molecules. Unfortunately, the conventional solution-based functionalization approach often leads to collapse of the CNT forest and hence a significant loss of binding sites. In this presentation we demonstrate that CNTs can be lithographically defined to form various structures that are resistant to liquid-induced collapse. We show that the CNT forest can be functionalized with 1,5-diaminonaphthalene as a linker molecule and its coverage can be characterized by fluorescence spectroscopy.