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  • NanoSEC Seminar Oct 7, 2011

    Engineered Nanoparticles for Tumor Imaging and Therapy

    Engineered Nanoparticles for Tumor Imaging and Therapy

    Guest: Dr. Jin Xie, Dept. of Chemistry and Bioimaging Research Center, the University of Georgia
    Friday, October 7, 2011 4:00 pm - 5:00 pm
    Location: Riverbend Research South Laboratory Auditorium

    Magnetic nanoparticles have long been an important class of biomaterials. Iron oxide nanoparticles, for instance, have been used in clinics as MR contrast probes, mostly for improving the visibility of lesions in reticuloendothelial system (RES) organs, such as liver and lymph nodes. Recently, a new set of chemistry has emerged, which allows one to prepare nanoparticles with fine control over a wide range of parameters, including size, shape, composition, magnetization, hydrodynamic size, surface coating and surface charge. Such a transition does not only affect the conventional applications of magnetic nanoparticles, but also opens many new avenues. The idea is to conceptualize a particle not only as a tiny magnetic crystal, but also as a platform of large surface-to-volume ratio. By harnessing the well-developed surface chemistry, one can load a wide range of functionalities onto the particle surface. These include biovectors--such as peptides and antibodies--which are able to steer the migration of nanoparticles in a living subject and to accumulate them preferentially in areas of interests, such as in tumors. The nanoplatforms can be further loaded with imaging motifs or therapeutic agents, and as a consequence, to be upgraded as multifunctional nanogadgets of multimodal imaging capabilities or theranostic features. In this talk I will introduce some of our recent work in this field.

     

  • CSP Lunch Seminar Oct 11, 2011

    Wang-Landau simulations of confined lattice proteins

    Wang-Landau simulations of confined lattice proteins

    Guest: Busara Pattanasiri
    Tuesday, October 11, 2011 12:30 pm - 1:30 pm
    Location: CSP Conference Room (322)

  • Departmental Colloquium Oct 13, 2011

    Driving to Contact: Single Molecular Electronics and Biophysics

    Driving to Contact: Single Molecular Electronics and Biophysics

    Guest: Dr. Bingqian Xu, UGA Engineering
    Thursday, October 13, 2011 4:00 pm - 5:00 pm
    Location: Auditorium 202

    Single molecule study, where science and engineering met, applies the tools and measurement techniques of nanoscale physics and chemistry to generate remarkable new insights into how physical, chemical, and biological systems function. It permits direct observation of molecular behavior that can be obscured by ensemble averaging and enables the study of important problems ranging from the fundamental physics of electronic transport in single molecule junctions and biophysics of single molecule interactions, such as the energetics and non-equilibrium transport mechanisms in single molecule junctions and the energy landscape of biomolecular reactions, associated lifetimes, and free energy, to the study and design of single molecules as devices-molecular wires, rectifiers and transistors and high‐affinity, anti‐cancer drugs.

    We will describe our pioneered highly integrated SPM-based approaches to (1) simultaneously fabricate, control, modulate, and monitor the electronic and mechanical properties of molecular junction devices at the single-molecule level. (2) Probe the biophysical mechanism of single‐molecule interactions, including the binding affinity and specificity. Our recent research examples will be used in the discussions.

  • CSP Lunch Seminar Oct 18, 2011

    Spin waves and optical illusions in the Heisenberg antiferromagnet on the kagome lattice

    Spin waves and optical illusions in the Heisenberg antiferromagnet on the kagome lattice

    Guest: Stefan Schnabel
    Tuesday, October 18, 2011 12:30 pm - 1:30 pm
    Location: CSP Conference Room (Room 322)

  • Departmental Colloquium Oct 20, 2011

    Strands of Superconductivity at the Nanoscale

    Strands of Superconductivity at the Nanoscale

    Guest: Dr. Paul Goldbart, Georgia Tech, School of Physics
    Thursday, October 20, 2011 4:00 pm - 5:00 pm
    Location: Auditorium, Physics 202

    Superconducting circuitry can now be fabricated at the nanoscale, e.g., by depositing suitable materials on to single molecules, such as DNA or carbon nanotubes.  I shall discuss various themes that arise when superconductivity is explored in this new regime, including the thermal passage over and quantum tunneling through barriers by the superconducting condensate as a whole, as well as a strange, hormetic effect that magnetism can have on nanoscale superconductors.  I shall describe nanoscale superconducting quantum interference devices, which are subtly sensitivity to magnetic fields and patterns of supercurrent -- features that hint at uses of superconducting nanocircuitry, e.g., in mapping quantum phase fields and testing for superconducting correlations in novel materials.  I shall also mention settings in which superconducting nanosamples show a particular sensitivity to their geometry or topology, and shall conclude by touching on two emerging themes: the interplay between graphene and superconductivity, and what nanoprobes might be revealing about exotic forms of superconductivity.

  • NanoSEC Seminar Oct 21, 2011

    Strain Effect Analysis on the Thermoelectric Figure of Merit in Si/Ge Nanocomposites

    Strain Effect Analysis on the Thermoelectric Figure of Merit in Si/Ge Nanocomposites

    Guest: Professor Gang Li, Department of Mechanical Engineering, Clemson University
    Friday, October 21, 2011 7:00 pm - 8:00 pm
    Location: Riverbend Research South Auditorium

    Thermoelectric (TE) energy conversion is a technology that converts thermal energy to electrical power and vice versa. Thermoelectric technology has significant advantages over other energy conversion technologies due to its compactness, high reliability and zero emissions of noise and pollutants. However, the energy conversion efficiency in existing thermoelectric devices is typically low. Since early 1990s, many studies have shown that higher energy conversion efficiency is achievable by reducing the phonon
    thermal conductivity of TE materials using nanostructured thermoelectric materials. While the future of the technology is promising, the performance of state-of-the-art nanostructured materials is still much less than that of the conventional energy conversion techniques. In this work, we suggest that, by utilizing the different responses of electron and phonon transport to mechanical strains, the efficiency of
    nanocomposite TE materials can be further improved through mechanical tuning. We perform computational analysis to investigate strain effect on the thermoelectric figure of merit in n-type Ge nanowire-Si host nanocomposite materials. The Seebeck coefficient and electrical conductivity of the Si/Ge nanocomposites are calculated by an analytical model derived from the Boltzmann transport equation (BTE) under the relaxation-time approximation. The effect of strain is incorporated into the BTE through strain induced energy shift and effective mass variation calculated from the deformation potential theory and a degenerate kp method. Strain effect on phonon thermal conductivity in the nanocomposites is computed through a model combining the strain dependent lattice dynamics and the ballistic phonon BTE. Electronic thermal conductivity is computed from electrical conductivity by using the Wiedemann-
    Franz law. Normal and shear strains are applied in the transverse plane of the Si/Ge nanocomposites. Thermoelectric properties including electrical conductivity, thermal conductivity, Seebeck coefficient and dimensionless figure of merit are computed for Si/Ge nanocomposites under these strain conditions.

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