The team of researchers from MIPT's Laboratory of Functional Materials and Devices
for Nanoelectronics, with the participation of their colleagues from the University of Nebraska (USA) and the University of Lausanne (Switzerland), have for the first time experimentally demonstrated that polycrystalline alloyed films of hafnium and zirconium oxides with a thickness of just 2.5 nm (see image below) retain their ferroelectric properties.
«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.
Not exact matches
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:
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.
Graphene shows promise
for use in
nanoelectronics, hydrogen storage, batteries and sensors.
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.
The Canadian Institute
for Advanced Research (CIAR) has a
nanoelectronics program led by Martin Moscovits.
«We thought it was a good candidate
for next - generation
nanoelectronics.
«On the way to breaking the terahertz barrier
for graphene
nanoelectronics.»
The composites are particularly well suited
for application in the up and coming field of
nanoelectronics.
Thermal fluids are used to alleviate wear on components and tools and
for machining operations like stamping and drilling, medical therapy and diagnosis, biopharmaceuticals, air conditioning, fuel cells, power transmission systems, solar cells, micro - and
nanoelectronic mechanical systems and cooling systems
for everything from engines to nuclear reactors.
This unforeseen result is very promising
for future applications in micro - and
nanoelectronics.»
The method is uniquely suited
for studying viruses and bacteria to facilitate development of medications, or
for imaging the structures of novel nanomaterials
for applications that range from
nanoelectronics to energy technology.
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.
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.
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.
Organic nanofibres show potential
for use in
nanoelectronics but are soft and fragile and have never been manipulated so deftly before, he says.
False - colour electron microscope image of the silicon
nanoelectronic device which contains the phosphorus atom used
for the demonstration of quantum entanglement.
Methods: Two - dimensional, sheet - like materials are of increasing interest
for use in filtration, sensing, and
nanoelectronics because of their unique properties.
Scientists hope to use graphene
for everything from
nanoelectronics and aircraft de-icers to batteries and bone implants.
Resume: Silicon nanowires have attracted high attention
for their possible application in
nanoelectronics and thermoelectricity.
Tour's scientific research areas include
nanoelectronics, graphene electronics, silicon oxide electronics, carbon nanovectors
for medical applications, green carbon research
for enhanced oil recovery and environmentally friendly oil and gas extraction, graphene photovoltaics, carbon supercapacitors, lithium ion batteries, CO2 capture, water splitting to H2 and O2, water purification, carbon nanotube and graphene synthetic modifications, graphene oxide, carbon composites, hydrogen storage on nanoengineered carbon scaffolds, and synthesis of single - molecule nanomachines which includes molecular motors and nanocars.
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.