SEPARATING THE HYPE AND THE BUZZ - Monday, November 30, 2009

NEWSWORTHY

Medical Imaging
Researchers from the National Institute of Standards and Technology and the National Institute of Allergy and Infectious Diseases have developed a procedure to illuminate the interior of cells by using nanoparticles. The study revealed information about the clustering mechanism in proteins inside a type of human red blood cells that allows them to be mechanically flexible. Their findings show that quantum dots can be used in investigating dynamic cellular processes. See AtoZ Nano, First Science, Nanotech Wire, Nanowerk, and Nanomedicine and Nanobiotechnology.

Beneficial defects in carbon nanotubes
Researchers from the University of California, San Diego discovered that defective carbon nanotubes can be used to store energy. They developed methods to control this capacity of storing charge by bombarding carbon nanotubes with Argon or Hydrogen. They also noted that defects created in a controlled manner could ultimately avoid deterioration of electrical conductivity. See AtoZ Nano, Nanotech Wire, Nanowerk, Nanovip, and Applied Physics Letters.

“Fly paper” to capture cancer cells
Researchers from the University of California, Los Angeles have created a three-dimensional nanostructed “fly paper” that can capture cancer tumor cells (CTCs) in the blood stream. It is estimated that the 1-by-2 centimeter nanopillar silicon chip coated with an antibody protein could detect 45 to 65 percent of cancerous cells in a medium of breast cancer cells. See AtoZ Nano, First Science, Nanotech Wire, Nanowerk, and Angewandte Chemie.

Waste heat to electricity
Researchers at MIT have developed a method to convert waste heat to useful electricity with both high efficiency and high throughput (electrical power). The existing systems of conversion demonstrate a 40 percent efficiency of the Carnot limit (energy conversion can never exceed the Carnot limit), while the new device (starting with a single quantum dot) can make this conversion with a possible efficiency of 90 percent of the limit. See AtoZ Nano, Nanotech Wire, Nanowerk, and Applied Physics Letters.

HONORABLE MENTIONS

Synthesizing Graphene
Extensive research is being conducted to develop two-dimensional graphene-like polymers. Their desirable electrical properties could ultimately lead to graphene replacing silicon in many semiconductors. Physicists at Empa, Switzerland along with chemists from the Max Planck Institute for Polymer Research in Mainz, Germany have synthesized a graphene-like porous polymer through a new method- “bottom-up” synthesis on metal surfaces. They allowed functionalized phenyl rings to grow into a two-dimensional structure on a silver substrate that created pores of a single-atom diameter with pore spacing of less than a nanometer. See AtoZ Nano, Nanotech Wire, Nanowerk, and Chemical Communications.

Nanostructure Vibrations
Scientists from the University of Melbourne and the University of Chicago have overcome the limitation many researchers have been facing to approach single-atom sensing through nano-scale vibrations. Vibrations at nanoscale can provide applications in ultrasensitive mass detection, molecular scale biological sensing, and an understanding of nanoscale mechanical losses. See AtoZ Nano, Nanotech Wire, Nanowerk, and Nature Nanotechnology.

Current through C60s
European scientists created minute electrical circuit between two molecules. In a controlled atmosphere two C60 molecules of 1nm in diameter were brought together and the current that passed through them was recorded. However, the conductance is a 100 times lesser than that of a single molecule. This new circuit can be used in devices to control leakage current between neighboring circuits. See AtoZ Nano, Nanowerk, and Physical Review Letters.

Nanophotonic forces
Researchers from the University of Ghent and the IMEC demonstrated repulsive and attractive forces in photons with spatial distribution of light. The study used advanced fabrication techniques to create to parallel nanoscale waveguides separated by a distance of 220nm on a silicon-on-insulator chip. When a laser passed through these waveguides optical forces were generated; the spatial distribution indicated the type of force-attraction or repulsion. This study provides applications in areas of telecommunication and signal processing. See Nanowerk and Nature Nanotechnology.