Nanotechnology Databases

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Nanotechnology Research Laboratories

 

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Showing results 76 - 100 of 132 for research and community organizations starting with S:

 
The research of the Dai Laboratory at Stanford interfaces with chemistry, physics, materials science and biophysics. Ongoing projects include developing new synthetic routes to ordered nanomaterial architectures; electrical, mechanical, electromechanical and electrochemical characterizations at the nanoscale; and probing the real-space structures and functions of biological molecules.
The group is interested in the theoretical and computational research of photonic crystals, micro-photonic and nano-photonic structures, as well as solid state devices.
The group's research is at the intersection of experimental condensed matter physics and nanoscale science and technology. Their efforts involve local probes, nanoassembly, collective phenomena, spin/charge manipulation, reduced-dimensional systems, and single quanta physics.
The Micro/Nano Systems and Technology Graduate Certificate offers a plan of study that focuses on the miniaturization technologies that have important roles in materials, mechanical, and biomedical engineering practice, in addition to being the foundation for information technology.
Single-molecule nanophotonics at Stanford University
The Molecular Imaging Program at Stanford (MIPS) was established as an inter-disciplinary program to bring together scientists and physicians who share a common interest in developing and using state-of-the-art imaging technology and developing molecular imaging assays for studying intact biological systems.
The Stanford Nanoelectronics Group was founded in September 2004 by Professor H.-S. Philip Wong. The group's research interests are in nanoscale science and technology, semiconductor technology, solid state devices, and electronic imaging.
The objective of this project is to develop optimized nanocomposite materials for high-density H2 reversible storage applications.
Research areas: nanophotonics, quantum optics, nonlinear optics, optoelectronics
The Nanoscale Materials Science Graduate Certificate offers an opportunity to acquire the knowledge and skills needed to understand the present and potential applications of these rapidly developing nano-materials technologies.
The Quantum Information Science group at Stanford University, lead by Professor Yoshihisa Yamamoto, conducts the basic research on quantum optics, semiconductor mesoscopic physics, nuclear and electron spin resonance, with emphasis on quantum information system applications.
CTSR is a designated US National Science Foundation Materials Research Science and Engineering Center and includes research on plasma-based ultrafine particle synthesis.
The mission of the Steacie Institute for Molecular Sciences (SIMS) is to provide leadership in collaboration with the Canadian and international scientific communities in the development of a knowledge base in molecular sciences and to ensure that it has positive impact on Canada by being pro-active in its dissemination to our partners.
The major research interests of the group are the design, fabrication, characterization and applications of various active nanostructures such as nanofibers, nanotubes, nanojunctions and nanotrees. The active materials currently under exploration include piezoelectric, piezoresistive or conductive, thermal electric and photovoltaic materials. The targeted applications of the various nanostructures developed are acoustic sensors for structural health monitoring, medical devices for thrombus retrieving, nanoacoustic waves for circulating cancer cell screening, chemical sensors for various gases and explosives, biosensors for stroke diagnostics, and energy scavenging involving mechanical-electric, thermoelectric, optoelectric and chemical-electric energy conversions.
Participation in the Nanotechnology Graduate Program leads to Masters of Science, Masters of Engineering, and Doctor of Philosophy in the respective disciplines with a designated nanotechnology concentration. To qualify for the nanotechnology concentration, in addition to satisfying disciplinary core requirements, candidates for Masters' degrees must complete the common core and a minimum of three elective courses and should attend regularly the seminar series in the Nanotechnology Curriculum.
Participation in the Nanotechnology Graduate Program leads to Masters of Science, Masters of Engineering, and Doctor of Philosophy in the respective disciplines with a designated nanotechnology concentration. To qualify for the nanotechnology concentration, in addition to satisfying disciplinary core requirements, candidates for Masters' degrees must complete the common core and a minimum of three elective courses and should attend regularly the seminar series in the Nanotechnology Curriculum.
Participation in the Nanotechnology Graduate Program leads to Masters of Science, Masters of Engineering, and Doctor of Philosophy in the respective disciplines with a designated nanotechnology concentration. To qualify for the nanotechnology concentration, in addition to satisfying disciplinary core requirements, candidates for Masters' degrees must complete the common core and a minimum of three elective courses and should attend regularly the seminar series in the Nanotechnology Curriculum.
The lab deals with Large-Area 3-D Nano-Patterning and Nanostructure Fabrication, Nanoscale Interfacial Phenomena, Multifunctional Superhydrophobic Surfaces, Microfluidic Self-Assembly of Nanomaterials, Nanofluidic Energy Harvesting, and Optofluidic Waveguides and Sensors.
The group is exploring nanoelectroics and nanomechatronics research areas based on low dimensional materials, including carbon nanotube, graphene and conjugated polymers.
The group is interested in studying the behavior of advanced material systems at the nanoscale. Particular material systems of interest include polymers and polymer nanocomposites, as well as thin film and piezoelectric materials of interest in MEMS applications.
The Multiscale Science, Engineering, and Technology research thrust at Stevens seeks to establish the knowledge base necessary to develop and implement nanotechnology-enabled solutions spanning a broad spectrum of engineering and science disciplines. Rooted in nanoscale science yet focused on real-world problems, these emerging technologies will have transformative value in areas of national and global interest including energy, health, electronics, communications, the environment, and national security.
The goal of the Nanotechnology Graduate Program is to create a vibrant interdisciplinary environment that provides stimulating and cross-fertilizing educational training in nanotechnology to contribute to the Institute's research excellence in related frontiers while preserving strong disciplinary fundamentals.
Part of the EU 'New Emerging Science and Technology' Programme, SIBMAR aims at high resolution structural information of individual biological molecules by employing coherent low energy electron waves.
The EU funded STREP project SUBTLE is associated with nanoelectronic devices in which quantum-confined electron channels are so closely spaced to each other that tailored feedback action exists. The approach of SUBTLE is based on the application of two effects in miniaturized electronics, which one usually tries to avoid in device design: back-action of the channel on the gate and noise induced switching.
A new institute supported by Samsung Advanced Institute of Technology
 
 
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