Highlights
Nov 28, 2012
Pennsylvania State University
Nanoscale Rockets Powered by Ultrasound
Wei Wang (Penn State), Angelica Castro (ESPCI), Mauricio Hoyos (ESPCI), Thomas Mallouk (Penn State)
MRSEC researchers working in an international collaboration with French scientists at ESPCI (Paris Tech) have discovered that rocket-shaped metallic micro-rods can be propelled through fluids using ultrasound, with fast translation towards the tapered end and rapid rotation & assembly of rods into circular chains that move like conveyer belts. Since most ways to make micro-objects move autonomously in fluids are incompatible with biological fluids, this bio-friendly ultrasound technique may be a first step towards the design of powered micro-robots that can perform microsurgery or deliver
Nov 7, 2012
University of Utah
Photochemically Mapping the Near-Fields of Plasmonic Nanocrescents
Objective: Use plasmon-enhanced photochemical reactions to map the polarization-dependent near fields of optical antennas. Approach: Use the anisotropic nano-crescent structure and SU-8 photo-resist. SU-8 exposure accomplished through plasmon-enhanced multi-photon absorption by 800 nm light.
Approach: Use the anisotropic nano-crescent structure and SU-8 photo-resist. SU-8 exposure accomplished through plasmon-enhanced multi-photon absorption by 800 nm light.
Sep 25, 2012
Georgia Institute of Technology
Tracking the Movement of Dopants in an Analog Memristor Using X-Ray Absorption Spectroscopy
Jordan Greenlee, James Compagnoni, Cole Petersburg, Faisal Alamgir, W. Alan Doolittle
Jordan Greenlee, James Compagnoni, Cole Petersburg, Faisal Alamgir, W. Alan Doolittle
1) Department of Electrical and Computer Engineering, Georgia Tech 2) Department of Materials Science and Engineering, Georgia Tech
Sep 25, 2012
Georgia Institute of Technology
International Programs Grow
Edward H. Conrad and Claire Berger
Edward H. Conrad and Claire Berger
School of Physics, Georgia Institute of Technology
Sep 25, 2012
Georgia Institute of Technology
Fibroblast Cell Adhesion on Dynamic Microgel Substrates
Hiroaki Yoshida, Jeffrey Gaulding, Apoorva Kalasuramath, Andrés J. García, L. Andrew Lyon
Hiroaki Yoshida, Jeffrey Gaulding, Apoorva Kalasuramath, Andrés J. García, L. Andrew Lyon School of Chemistry and Biochemistry, Petit Institute for Bioengineering and Bioscience, Woodruff School of Mechanical Engineering, Georgia Institute of Technology
Sep 19, 2012
Georgia Institute of Technology
An Electron's Life on the Edge
David B. Torrance, Baiqan Zhang, Tien Hoang and Phillip N. First
David B. Torrance, Baiqan Zhang, Tien Hoang and Phillip N. First School of Physics, Georgia Tech
Sep 19, 2012
Georgia Institute of Technology
Epitaxial Graphene’s Edge
Ming Ruan, Yike Hu, James Palmer, Tom Guo, John Hankinson, Rui Dong, Claire Berger, Walt de Heer
Ming Ruan, Yike Hu, James Palmer, Tom Guo, John Hankinson, Rui Dong, Claire Berger, Walt de Heer School of Physics, Georgia Tech
Sep 6, 2012
Highly Stretchable and Tough Hydrogels
Sun, J.-Y., X. Zhao, W. R. K. Illeperuma, O. Chaudhuri, K. H. Oh, D. J. Mooney, J. J. Vlassak and Z. Suo
Hydrogels are used as scaffolds for
tissue engineering, vehicles for drug delivery, actuators for optics and
fluidics, and model extracellular matrices for biological
studies. The scope of hydrogel applications, however, is often severely limited
by their mechanical behaviors. Most hydrogels are brittle, sensitive to
notches, and do not exhibit high stretchability. We report the synthesis of hydrogels
from polymers forming ionically and covalently crosslinked networks.
Although such gels contain 90% water, they can be stretched beyond 20 times
Sep 5, 2012
Cornell University
Precise Stitching, Not Patch Size, Determines the Quality of Atomic Quilts
A. W. Tsen, et al. Science, in press.
Intergrain stitching determines electrical conductance across graphene grain boundaries
The outstanding electronic and mechanical properties of
single-atom-thick layers of carbon, so-called “graphene” films, make
them ideal for next-generation solar cells and transistors. However,
attempts to grow these films over large areas invariably lead to
quilt-like structures of interconnected atomically-perfect patches
Aug 27, 2012
Cornell University
Controlling and Imaging Electron Motions in Atomic-Scale Sandwiches
E. J. Monkman, C. Adamo, et al. Nature Materials (in press)
A new instrument allows the first imaging
of the movement of electrons in artificial materials
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