Sentences with phrase «in nanoelectronics»
Imec, the world - leading research and innovation hub in nanoelectronics and digital technologies, today announced at its Imec Technology Forum (ITF) Health event, that is...
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Resume: Silicon nanowires have attracted high attention for their possible application in nanoelectronics and thermoelectricity.
Organic nanofibres show potential for use in nanoelectronics but are soft and fragile and have never been manipulated so deftly before, he says.
The work could have applications in nanoelectronics and drug development.
Many networks have been created to promote cooperation between companies and universities, as well as recruitment, such as the E.U. - funded Mathematics, Computing, and Simulation for Industry (MACSI) project, the European Consortium for Mathematics in Industry (ECMI), the European Community on Computational Methods in Applied Sciences (ECCOMAS), the Network on Computations in Commutative Algebra, and the newly established Marie - Curie Research Training Network in Coupled Multiscale Simulation and Optimization in Nanoelectronics (COMSON) project.
Co-author Dr Themis Prodromakis Reader in Nanoelectronics and EPSRC Fellow in Electronics and Computer Science at the University of Southampton, said: «The uptake of any new technology is typically hampered by the lack of practical demonstrators that showcase the technology's benefits in practical applications.
This research was jointly carried out with Fedor Jelezko, a professor at the University of Ulm in Germany, as part of Japan - Germany joint research (in nanoelectronics) on «quantum computing in isotopically engineered diamond,» supported by the JST Strategic International Collaborative Research Program.
Graphene shows promise for use in nanoelectronics, hydrogen storage, batteries and sensors.
Computing based on photons in nanoelectronic circuits can be then achieved in future computer components.
Not exact matches
Working with Mohawk Valley EDGE, we are in a position to begin construction of infrastructure and site improvements while we continue to market this site globally to the semiconductor and nanoelectronics industry.
Located at SUNY POLY's Marcy Campus, in the heart of New York's Nanoelectronics Manufacturing and R&D Cluster, Marcy Nanocenter provides unique opportunities for collaboration with partners such as:
In this episode, Scientific American's «SA 50» research leader of the year, MIT's Angela Belcher, discusses her work using viruses and other organisms to help create nanoelectronics.
I became interested in BME while working at CTF Systems, a company that uses quantum nanoelectronic devices manufactured with conventional microfabrication techniques to manufacture medical imaging (MEG) systems.
Their findings could have implications for optimising the thermal budget of nanoelectronic devices - which means they could help dissipate the total amount of thermal energy generated by electron currents - or in the production of energy through thermoelectric effects in novel nanomaterials.
If a similar approach can be used in thermal transport, that could facilitate development of more efficient thermoelectric and nanoelectronic devices, improved thermal barrier coatings, and new materials with ultralow thermal conductivity.
This program is aimed at assisting Canadian researchers who are making internationally recognized contributions in fields directly relevant to novel nanoelectronic technologies, and who will benefit particularly by the networking and interactions characteristic of all CIAR programs.
As a result, graphene finds a multitude of applications in modern nanoelectronics.
This much simpler thermodynamic approach to the electrical conduction in graphene will allow scientists and engineers not only to better understand but also to improve the performance of graphene - based nanoelectronic devices.
The composites are particularly well suited for application in the up and coming field of nanoelectronics.
This unforeseen result is very promising for future applications in micro - and nanoelectronics.»
These include nanoelectronic scaffolds that could become the foundation for engineered tissues that are used to detect and report on a variety of health problems and or atomic - scale memory and logic devices that be used in smartphones.
The ability to characterize single molecules using highly sensitive nanoelectronics is an exciting prospect in the field of sensors, particularly for neuro - and biosensor applications.
Professor Ravi Silva, Director of the ATI and Head of the Nanoelectronics Centre (NEC) at the University of Surrey said: «In the future, carbon nanotube modified carbon fibre composites could lead to exciting possibilities such as energy harvesting and storage structures with self - healing capabilities.
«Since the structures of this material are compatible with silicon technology, we can expect that new non-volatile memory devices with ferroelectric polycrystalline layers of hafnium oxide will be able to be built directly onto silicon in the near future,» says the corresponding author of the study and head of the Laboratory of Functional Materials and Devices for Nanoelectronics, Andrei Zenkevich.
In addition to the three existing partnerships, two overlapping JTIs for so - called embedded systems (ARTEMIS) and nanoelectronics (ENIAC) will be merged into one program for electronic components and systems.
A spin wave can be thought of as similar to an ocean wave, which keeps water molecules in essentially the same place while the energy is carried through the water, as opposed to an electric current, which can be envisioned as water flowing through a pipe, said principal investigator Kang L. Wang, UCLA's Raytheon Professor of Electrical Engineering and director of the Western Institute of Nanoelectronics (WIN).
Led by Professor Christian Schönenberger, scientists in Basel are now taking a similar approach to nanoelectronics.
In this episode, journalist Philip Ross discusses his article in the October Scientific American, called «Viral Nanoelectronics,» about wires, batteries and microchips constructed out of viruseIn this episode, journalist Philip Ross discusses his article in the October Scientific American, called «Viral Nanoelectronics,» about wires, batteries and microchips constructed out of virusein the October Scientific American, called «Viral Nanoelectronics,» about wires, batteries and microchips constructed out of viruses.
The article, in the October issue of Scientific American, [is] «Viral Nanoelectronics.»
Methods: Two - dimensional, sheet - like materials are of increasing interest for use in filtration, sensing, and nanoelectronics because of their unique properties.
«This technique should enable a wide range of previously inaccessible experiments and applications in fields as diverse as nanoelectronics, optoelectronics and bioengineering.»
Kater Murch, PhD, an assistant professor of physics at Washington University in St. Louis, and collaborators Steven Weber and Irfan Siddiqui of the Quantum Nanoelectronics Laboratory at the University of California, Berkeley, have used a superconducting quantum device to continuously record the tremulous paths a quantum system took between a superposition of states to one of two classically permitted states.
Dr. Han You and Professor Andrew Steckl of the Nanoelectronics Laboratory at the University of Cincinnati have experimentally demonstrated the new display for the first time, with their results published in a recent issue of Applied Physics Letters.