The first optical tests of this new type of metallic microstructure confirmed
its photonic properties.
I can only assume that WebHubTelescope has a further list of CO2's «magical
photonic properties» that don't have»... experimental support...»
He hasn't provided examples of any «magical
photonic properties».
«CO2 does have some magical
photonic properties that have experimental support and, perhaps more important, practical applications.»
Photonic properties can be gained using SNOM.
Not exact matches
García - Garibay hopes to design crystals that take advantage of
properties of light, and whose applications could include advances in communications technology, optical computing, sensing and the field of
photonics, which takes advantage of the
properties of light; light can have enough energy to break and make bonds in molecules.
The conducting electrons at the interface form a two - dimensional electron gas (2DEG) which boasts exotic quantum
properties that make the system potentially useful in electronics and
photonics applications.
By tying substances like this in knots, the researchers hope to understand how their intricate configurations and unique
properties can be harnessed in the next generation of advanced materials and
photonic devices.
For decades, silicon has been the foundation of the microelectronics revolution and, owing to its excellent optical
properties in the near - and mid-infrared range, is now promising to have a similar impact on
photonics.
Although this method was developed with upconversion nanoparticles, the researchers believe their new «direct - doping» approach can be generalised to other nanoparticles with interesting
photonic, electronic and magnetic
properties.
One of the great opportunities this study creates is the ability to produce multi-functional inorganic materials such as metals and ceramics to explore
photonic and energy harvesting
properties in these new materials
Shaping nanometric gold particles — of the size of millionths of a millimeter — to improve their
properties in biomedicine and
photonics has been made possible thanks to a special laser system in a work carried out at the Universidad Complutense de Madrid (UCM) and now published in Science.
«This is an interesting development, not just because Weyl points have been experimentally observed, but also because they endow the
photonics crystals which realize them with unique optical
properties,» says Ashvin Vishwanath, a professor of physics at the University of California at Berkeley who was not involved in this research.
The result opens the door for more careful study of this region of materials, with a view to finding a material that can offer just the right
properties for certain
photonics applications.
Philipp Hauke and Peter Zoller from the Department of Theoretical Physics at the University of Innsbruck and the Institute for Quantum Optics and Quantum Information (IQOQI) at the Austrian Academy of Sciences in collaboration with Markus Heyl from the Technical University of Munich, and Luca Tagliacozzo from ICFO — The Institute of
Photonic Sciences have found a new way to detect certain
properties of many - particle entanglement independent of the size of the system and by using standard measurement tools.
«Basically, we need to recognize that some of these structures can exhibit
properties of
photonic crystals, and we need to take their physics into account,» Semouchkina says.
«We found that the
properties that go along with being a
photonic crystal can mask the resonance of metamaterials, to the point they can cause unusual refraction — including negative refraction, which is necessary for the development of a perfect lens,» Semouchkina says.
The functionalized carbon nanotubes have significant prospects for further development, Doorn noted, including advances in functionalization chemistry; integration into
photonic, plasmonic and metamaterials structures for further control of quantum emission
properties; and implementation into electrically driven devices and optical circuitry for diverse applications.
The finding that a single layer of atoms modifies
properties of light and other electromagnetic radiation has implications for controlling light at subwavelength scales in
photonic devices such as LEDs and photovoltaic cells.
The latest investigations on the thermal
properties of silicon, the most common material in electronics, micro - and nano - electro - mechanical systems (MEMS and NEMS) and
photonics, have pointed to nanostructuring as a highly efficient approach to acoustic phonon engineering [1 - 3].
As described Aug. 10 in the journal Nature Nanotechnology, Hybrid
Photonic - Nanomechanical Force Microscopy (HPFM) can discern a sample's topographic characteristics together with the chemical
properties at a much finer scale.
«Expanding this methodology to non-biological crystalline materials will result in microscale architectures with enhanced
photonic, electronic, and catalytic
properties,» said Tanya Shirman, a postdoctoral fellow at SEAS and Technology Development Fellow at Wyss Institute and co-author of the research.
Research in the Bredas group focuses on computational materials chemistry: computational methods are used as a tool to uncover the
properties of novel advanced materials, understand their chemistry and physics, and derive an integrated understanding of the intrinsic molecular - and nano - scale processes in a variety of emerging applications (such as solar cells or low - power displays), especially in the fields of organic electronics,
photonics, and information technology.
Andrew Steckl, an expert in
photonics from the University of Cincinnati, has been working to intensify the
properties of LEDs by using biological materials - specifically DNA from salmon sperm.