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.
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.
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.
Although some of my research focuses on the development of
nanoelectronic devices for life science applications (as well as for telecommunications and radio astronomy), most of my research efforts are based on the use of microfluidic chips (MFCs) with molecular biology.
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.
False - colour electron microscope image of the silicon
nanoelectronic device which contains the phosphorus atom used for the demonstration of quantum entanglement.
Not exact matches
One application could involve the guided self - assembly of
nanoelectronic components into three - dimensional circuits and whole
devices.
Ferroelectric power affects a number of technologies, including cloud computing, sensing
devices, solar energy systems 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.
«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.
Nanomedicine varieties from the medical solicitations of Nano materials and biological
devices, to
Nanoelectronic biosensors, and even potential future applications of molecular nanotechnology such as biological machineries.
Nanoelectronics: Electronics on a nanometer scale, whether made by current techniques or nanotechnology; includes both molecular electronics and nanoscale
devices resembling today's semiconductor
devices.
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.