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Todd D. Krauss
Nanoscale Materials and Devices
Associate Professor of Chemistry
Ph.D. 1998, Cornell University

Our main research area concerns understanding the fundamental properties of materials with a size in between individual molecules and the bulk. These nanometer scale materials have physical characteristics that are strong functions of their size and shape. Thus, they have properties that can be easily manipulated. Our investigations in this area are currently focused on fundamental studies of carbon nanotubes and semiconductor nanocrystals, and the integration of these materials into both novel photonic devices and biological sensors. These studies are highly interdisciplinary, and lie at the interface between chemistry, physics, applied physics, and materials science.

Carbon nanotubes consist of a hexagonal network of carbon atoms rolled up into a cylinder. Nanotubes are typically microns long, while their diameter is usually only around 1 nanometer. The quantum confinement of electrons around the nanotube results in unexpected electronic properties. For example, carbon nanotubes can be either metallic or semiconducting, depending on the diameter and helicity of the carbon lattice. We are concerned with determining fundamental electronic and optical characteristics of single carbon nanotubes (Figure 1). These investigations are carried out using atomic force microscopy, as well as single molecule and ultrafast optical spectroscopy.

Figure 1. Fluorescence spectra and (Bottom) fluorescence images from individual single walled carbon nanotubes (Data acquired with L. Novotny and A. Hartschuh).
Figure 2. Fluorescence from different sized CdSe quantum dots.

Inorganic semiconductor particles containing a few thousand atoms, known as semiconductor quantum dots (Figure 2) also have unique electronic and optical properties. Using state-of-the-art experimental techniques (electrostatic force microscopy and single nanocrystal optical spectroscopy), we are investigating the optical emission characteristics of individual quantum dots and the effect of permanent charges on this emission.

A significant remaining challenge for materials chemistry is to connect nanometer-sized materials to the macroscopic world. To that end, we are also developing simple synthetic methods to make nanocrystals and carbon nanotubes, and are exploring chemical modification of their surfaces. Our eventual goal is to build both integrated optical devices and biological sensors using nanomaterials as building blocks. Also, in collaboration with Professor Bren from the University of Rochester, we have began experiments to understand the folding of proteins (cytochromes c) on the single molecule level.

Relevant Publications
Peterson, J. J., Krauss, T. D.  "Fluorescence Spectroscopy of Single Lead Sulfide Quantum Dots,"  Nano Lett.  20066510.
Huang, L., Krauss, T. D.  "Quantized Bimolecular Auger Recombination of Excitons in Single-Walled Carbon Nanotubes,"  Phys. Rev. Lett.  200696057407.
Du, H., Strohsahl, C. M., Camera, J., Miller, B. L., Krauss, T. D.  "Sensitivity and Specificity of Metal Surface Immobilized Molecular Beacon Biosensors,"  J. Am. Chem. Soc.  20051277932.
Hahn, M. A., Tabb, J., Krauss, T. D.  "Detection of Single Bacterial Pathogens with Semiconductor Quantum Dots,"  Anal. Chem.  2005774861.
Krishnan, R., Hahn, M. A., Yu, Z., Thomas, M., Silcox, J. Fauchet, P. M., Krauss, T. D.  "Polarization Surface-charge Density of Single Semiconductor Quantum Rods,"  Phys. Rev. Lett.  200492216803.
Hartusch, A., Pedrosa, H. N., Novotny, L., Krauss, T. D.  "Simultaneous Fluorescence and Raman Scattering from Individual Single-Walled Carbon Nanotubes,"  Science  20033011354.
Wang, Z., Pan, S., Krauss, T.D., Du, H., Rothberg,L.J.  "The Structural Basis for Giant Enhancement Enabling Single Molecule Raman Spectroscopy,"  Proc. Natl. Acad. Sci. U.S.A.  20031008638.
Poitras, C. B., Lipson, M., Hahn, M. A., Du, H; Krauss, T. D.  "Photoluminescence Enhancement of Colloidal Semiconductor Quantum Dots Embedded in a Monolithic Microcavity,"  Appl. Phys. Lett.  2003824032.
Haremza, J. M., Hahn, M. A., Krauss, T. D., Chen, S., Calcines, J.  "Attachment of Single CdSe Nanocrystals to Individual Single-walled Carbon Nanotubes,"  Nano. Lett.  200221253.
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