"Nanomanipulation set-up assembles single-nanoparticle electronics".
Nanoparticles possess several advantages over 1D and 2D structures. For instance, in nanoparticles the carrier travelling distance is short and the carrier lifetime is long. However, connecting electrodes to a single nanoparticle is not a trivial task, which presents an obstacle to progress in areas such as electronics and optoelectronics. Devices containing randomly spread particles atop closely spaced leads made by break junction or tilt-angle evaporation techniques have been demonstrated, but developers would prefer a more routine approach.
Recently, researchers from the Institute of Physics, Academia Sinica, in Taiwan, have proposed and demonstrated a reliable approach for producing nanoparticle devices. The circuits fabricated by the team contain a single ZnO particle embedded in a nanopore structure and exhibit photovoltaic functionality with a fill factor of 48%.
Suits most materials
What’s more, the method provides a route for making electronic devices containing a single nanoparticle of virtually any material. Based on the device fabrication process, the team is now developing a technique that allows the chemical potential of an embedded nanoparticle to be tuned by a surrounding gate electrode. In this way, field-effect transistors containing a single semiconductor nanoparticle could be reproducibly constructed.
In a related project, the scientists have also used the manipulation probes to pick up selected objects such as nanowires, nanotubes and graphene sheets and place them on top of pre-prepared electrodes crossing the holes on a chip. This would allow for correlated structural TEM inspection and rigorous electrical characterization on the same specimen.
"Nanomanipulation set-up assembles single-nanoparticle electronics".
Linh-Nam Nguyen, Ming-Chou Lin, Horng-Shyang Chen, Yann-Wen Lan, Cen-Shawn Wu, Kuei-Shu Chang-Liao and Chii-Dong Chen.Nanotechnology 23 (2012) 165201 (6pp).
doi:10.1088/0957-4484/23/16/165201.
1 comment:
Both of these issues are longstanding DOE and Department of Defense concerns. The research also suggests a viable engineering method for synthesizing magnetic Fe3O4 nanoparticles and tailoring the surface chemistry toward specific heavy-metal contaminants of concern, including lead, mercury, cadmium, silver, copper, cobalt, and thallium. Nanoparticle Characterization Techniques
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