while also being light in weight he said. The molecule they compressed is benzene a flat ring containing six carbon atoms and six hydrogen atoms.
and the Carnegie Institution for Science including X-ray diffraction neutron diffraction Raman spectroscopy first-principle calculations transmission electron microscopy and solid-state nuclear magnetic resonance (NMR).
#Designing complex structures beyond the capabilities of conventional lithography Gold nanoparticles smaller than 10 nanometers spontaneously self-organize in entirely new ways
Using electron-beam lithography techniques the team carved out an array of inward tapering trenches designed to fit 1 to 3 rows of gold nanoparticles.
or light sources this is a groundbreaking new direction. The research team received funding for their study from the Israel Ministry of Science and Technology the European Research Council and the Biotechnology and Biological sciences Research Council.
Then, in May 2014, scientists from the University of California, Irvine, showed for the first time that these sensors can also be used to improve signals in a related imaging mode known as inelastic electron tunnelling spectroscopy.
"We believe that the results of this work are an important contribution to the use of inelastic electron tunnelling spectroscopy that will allow the technique to be used as an additional source of information in materials science
Piero Baglioni sheds light on the main benefits of these new products the advances made by his team
Next a mixture of two polymers are added to the metal substrate to create patterns a process known as diblock copolymer lithography (BCP.
and manipulation including deep ultraviolet light. These applications are possible because nanoporous materials facilitate anomalous enhancement of transmitted
(or reflected light through the tunneling of surface plasmons a feature widely usable by light-emitting devices plasmonic lithography refractive-index-based sensing and all-optical switching.
#Breakthrough in flexible electronics enabled by inorganic-based laser lift off Flexible electronics have been touted as the next generation in electronics in various areas ranging from consumer electronics to bio-integrated medical devices.
A research team headed by Professor Keon Jae Lee of the Department of Materials science and engineering at KAIST provides an easier methodology to realize high performance flexible electronics by using the Inorganic-based Laser Lift off (ILLO.
The ILLO process involves depositing a laser-reactive exfoliation layer on rigid substrates and then fabricating ultrathin inorganic electronic devices e g. high density crossbar memristive memory on top of the exfoliation layer.
By laser irradiation through the back of the substrate only the ultrathin inorganic device layers are exfoliated from the substrate
as a result of the reaction between laser and exfoliation layer and then subsequently transferred onto any kind of receiver substrate such as plastic paper and even fabric.
"AFM can reveal far smaller structures than optical microscopes, "Dr Hoogenboom explained, "but it's feeling rather than seeing.
With this technology a low-power laser beam is directed at the tumor where a small amount of magnetic iron-oxide nanoparticles are present either by injecting the particles directly into the tumor
Sufficient heat is generated then locally by the laser light raising the tumor temperature rapidly to above 43 degrees Celsius
so they can be detected by a photon laser light. The laser light heats the nanoparticles to at least 43 degrees Celsius to kill the cancer cells ultimately leaving all the other cells in the body unharmed.
The procedure can ultimately be carried out by the patient following training to direct a small laser light device to the affected area for a specified amount of time two to three times a day.
This method can ultimately improve the success rate as well as cut costs to the patient. This gives point
Each pixel can exhibit one of two colors depending on the polarization of the light used to illuminate it.
but instead the depth perception and 3d effect is created simply by viewing the print through an optical microscope coupled with polarizers.
metal nanostructures can scatter different wavelengths (colors) of light due to the fact that the tiny nanostructures themselves resonate at different wavelengths.
or rectangle) its resonance will depend on the polarization of the incident light. By tailoring the exact dimensions of the biaxial nanopixels researchers can generate different colors under different polarizations.
Because these shapes are biaxial they exhibit plasmonic resonances at different wavelengths for each axis with the colors determined almost entirely by the dimension of the axis parallel to the polarization direction.
For example a 130-nm x 190-nm elliptical pixel appears green under y-polarized light
or holography Yang said. 3d security elements that are difficult to replicate and which offer different levels of authentication could also be generated for anti-counterfeiting and anti-forgery technologies.
Meta-hologram produces dual images and multiple colors (w/Video) More information: Xiao Ming Goh et al.
First it lights up when it detects tumour cells to allow scientists to take a better look.
when it is activated by near-infrared light emitted by an imaging device and only if tumour cells release small signalling molecules.
Prof Zhang said the use of near-infrared light which is invisible to the human eye is unique as most imaging techniques use ultraviolet light or visible light.
Near-infrared light can penetrate 3 to 4 cm beyond the skin to deep tissue much deeper than visible light.
It also does not cause any damage to healthy cells unlike ultraviolet or visible light added Prof Zhang a materials expert.
Visible light also causes photo bleaching which is the destruction of the fluorescence dye that reduces the amount of time doctors
#The drugs are released when the biomarker lights up in response to the near-infrared light. This is the first time we are able to do bio-imaging
and then hardening it with the light of a camera flash. The resulting device responded to touch even
#Study suggests light may be skewing lab tests on nanoparticles'health effects Truth shines a light into dark places.
It turns out that previous tests indicating that some nanoparticles can damage our DNA may have been skewed by inadvertent light exposure in the lab. Nanoparticles made of titanium dioxide are a common ingredient in paint
where they help block ultraviolet light) and even within it (in foodstuffs such as salad dressings to make them appear whiter).
It is well known that in the presence of light and water, these particles can form dangerous, highly reactive chemicals called free radicals that can damage DNA.
Because light does not reach the human body's interior, scientists have accepted long that these nanoparticles would not damage cells by forming free radicals from light activation.
or ultraviolet light while others were kept carefully and intentionally in complete darkness from the moment of exposure to the time the DNA damage was measured.
or ultraviolet light did the DNA form base lesions, a form of DNA damage associated with attack by radicals.
The culprit in earlier studies may be ambient light from the laboratory that inadvertently caused DNA damage."
and using a blue backlight to energize them, QD Vision has developed an optical component that can boost the color gamut for LCD televisions by roughly 50 percent,
pixels are illuminated by a white LED backlight that passes through blue, red, and green filters to produce the colors on the screen.
But this actually requires phosphors to convert a blue light to white; because of this process, much light is lost,
and displays only reach about 70 to 80 percent of the National Television Standard Committee color gamut.
Manufacturers use a blue LED in the backlight, but without the need for conversion phosphors.
As blue light passes through the Color IQ tube, some light shines through as pure blue light
With more light shining through the pixels, LCD TVS equipped with Color IQ produce 100 percent of the color gamut,
and they can be used in dim light; they will even work on a cloudy day.""Or indoors,"Lou said."
titanium dioxide and light-capturing organic dye particles, the largest cells were only 350 microns thickhe equivalent of about two sheets of papernd could be flexed easily and repeatedly.
Photonic systems could eventually replace electronic ones, but the fundamentals of computation, mixing two inputs into a single output, currently require too much space and power when done with light.
Researchers at the University of Pennsylvania have engineered a nanowire system that could pave the way for this ability,
and using an optical cavity to amplify the intensity of the output to a usable level.
but it's not easy to do with light, as light waves don't normally interact with one another."
"The difficulty inherent in"mixing"light may seem counterintuitive, given the gamut of colors on TV
Red and blue light are experienced simply simultaneously, rather than combined into a single purple wavelength. So-called"nonlinear"materials are capable of this kind of mixing,
but even the best candidates in this category are not yet viable for computational applications due to high power and large volume constraints."
"but you need a powerful laser, and, even so, the material needs to be a many micrometers
"To reduce the volume of the material and the power of the light needed to do useful signal mixing,
but, by changing the polarization of the light as it entered the nanowire, the researchers were able to better confine it to the frequency-altering, nonlinear part of the device:
so that light is contained mostly within the cadmium sulfide rather than at the interface between it and the silver shell,
Ultimately, we want to be able to tune the light to whatever frequency is needed, which can be done by altering the size of the nanowire and the shell."
The researchers'optical cavity was able to increase the output wave's intensity by more than a thousand times."
either using optical (light-based) detection where nanoparticles are used to either emit light directly or change the optical properties of their surroundings or magnetic systems.
and then get heated up by a beam of light to destroy the cancer cells. This now has got as far as human trials for head
Using electron beam lithography she then stamps the pattern onto a polymer matrix and the nanowires are grown by applying electric current through electrodeposition.
Controlling photoluminescence with silicon nanophotonics for better device e
#Micro-and nano-swimmers can be propelled through media similar to bodily fluids Micro -or even nanorobots could someday perform medical tasks in the human body.
#Method for symmetry-breaking in feedback-driven self-assembly of optical metamaterials (Phys. org) If you can uniformly break the symmetry of nanorod pairs in a colloidal solution you're a step ahead of the game toward achieving new and exciting metamaterial properties.
Zhang and his group demonstrated self-assembled optical metamaterials with tailored broken-symmetries and hence unique electromagnetic responses that can be achieved via their new method.
The paper is titled Feedback-driven self-assembly of symmetry-breaking optical metamaterials in solution. We developed an innovative self-assembly route
or focus ion beam lithography that often results in strongly anisotropic and small-scale metamaterials. People build metamaterials using top-down methods that include light exposure
The team used a laser to excite the plasmonic resonance of specific particles produced in the reaction.
As a demonstration in our paper we have synthesized a new class of symmetry-breaking optical metamaterials that have isotropic electromagnetic responses
These antennae concentrate the light shining on them into tiny regions located in the gap between the nano particles.
what gap was required between particles to best concentrate the light but we now have the technology to test it.
Previous attempts by other research teams to visualise nanodiamonds under powerful light microscopes have run into the obstacle that the diamond material per se is transparent to visible light.
and far more stably via the interaction between the illuminating light and the vibrating chemical bonds in the diamond lattice structure which results in scattered light at a different colour.
The paper describes how two laser beams beating at a specific frequency are used to drive chemical bonds to vibrate in sync.
and generate a light, called coherent anti-Stokes Raman scattering (CARS). By focusing these laser beams onto the nanodiamond,
a high-resolution CARS image is generated. Using an in-house built microscope, the research team was able to measure the intensity of the CARS light on a series of single nanodiamonds of different sizes.
and spectroscopy techniques where beams of high-frequency photons bombard and bounce off a material to reveal elemental structure and composition.
These x-ray studies were conducted at Brookhaven's National Synchrotron Light source (NSLS. We were able to test the battery cycling in situ meaning we could watch the effects of increasing heat in real time said Brookhaven Lab chemist and study coauthor Seong Min Bak.
While they further confirmed the results with x-ray absorption spectroscopy and electron microscopy after the heating trials the team needed to map the changes at higher resolutions.
To capture the atoms'electronic structures the scientists used electron energy loss spectroscopy (EELS. In this technique measurements of the energy lost by a well-defined electron beam reveal local charge densities and elemental configurations.
Brookhaven's National Synchrotron Light source II will be a game-changer for this kind of experimentation and
Gold nanoparticles on the surface of the receptacle change the colour of the light detected by the instrument.
the gold nanoparticles change the colour of the light detected by the instrument. And the colour of the light detected reflects the exact concentration of the drug in the blood sample.
The accuracy of the measurements taken by the new device were compared with those produced by equipment used at the Maisonneuve-Rosemont Hospital in Montreal."
With gold as a chemically inert electrode and slightly-saline water as an electrolyte Salmeron and colleagues used a new twist on x-ray absorption spectroscopy XAS) to probe the interface
Our eyes recognize many materials by their characteristic colors which are related to their visible light absorption spectra.
The x-ray photons used in this study have energies that are about 250 times higher than those of visible light
and are generated at Berkeley Lab's Advanced Light source (ALS). Typical XAS measurements are made under vacuum conditions as x-rays are absorbed readily by matter even the nitrogen molecules in air.
This study which is reported in Science in a paper titled The structure of interfacial water on gold electrodes studied by x-ray absorption spectroscopy marks the first time that the scientific community has shown such high sensitivity in an in-situ environment under working electrode conditions s
The optical lithography techniques used to create the masks in a process akin to old-school wet photography are simply not capable of reliably reproducing the extremely small
"The issue in semiconductor lithography is not really making small featuresou can do thatut you can't pack them close together,
or"soft"X rays produced by the Advanced Light source at Lawrence Berkeley National Labs to probe the structure of the BCP film from multiple angles.
although the basic technique was developed using short wavelength"hard"X rays that have difficulty distinguishing two closely related polymers,
much better results can be obtained using longer wavelength X rays that are more sensitive to differences in the molecular structure.**
Its extreme thinness enables nearly all light to pass through across a wide range of wavelengths.
and optogenetics which involves genetically modifying cells to create specific light-reactive proteins. RE-NET seeks to develop new tools
or light to temporarily activate neurons. Therefore it could not only provide better observation of native functionality
The resulting products display a foam-like porous structure ideal for maximizing the benefits of graphene with the porosity tunable from ultra-light to highly dense through simple changes in experimental conditions.
Brighter new energy saving flat panel lights based on carbon nanotubes Even as the 2014 Nobel prize in Physics has enshrined light emitting diodes (LEDS) as the single most significant and disruptive energy-efficient lighting solution of today scientists
Scientists from Tohoku University in Japan have developed a new type of energy-efficient flat light source based on carbon nanotubes with very low power consumption of around 0. 1 Watt for every hour's operation
or cathode and scratched the surface with sandpaper to form a light panel capable of producing a large stable and homogenous emission current with low energy consumption.
Brightness efficiency tells people how much light is being produced by a lighting source when consuming a unit amount of electric power
Although the device has a diode-like structure its light-emitting system is not based on a diode system
Field emission electron sources catch scientists'attention due to its ability to provide intense electron beams that are about a thousand times denser than conventional thermionic cathode (like filaments in an incandescent light bulb.
Many researchers have attempted to construct light sources with carbon nanotubes as field emitter Shimoi said. But nobody has developed an equivalent and simpler lighting device.
The ability to mold inorganic nanoparticles out of materials such as gold and silver in precisely designed 3-D shapes is a significant breakthrough that has the potential to advance laser technology microscopy solar cells electronics environmental testing
and an imaging function all stimulated on demand by a single light source. The nanoparticles also include the cell-targeting property essential for treating
The system is built around a polyethylene-glycol-based polymer that carries a small peptide component that allows it to bind preferentially to specific cell types The polymer itself serves as a photosensitizer that can be stimulated by light to release reactive oxygen species (ROS.
and chemotherapy with triggered drug release through one light switch explains Liu emphasizing the significance of the system.
The white light used in this work does not penetrate tissue sufficiently for in vivo applications Liu explains
but we are now attempting to use near-infrared laser light to improve the tissue penetration and move toward on-demand cancer therapy.
and chemotherapy with on-demand drug release upon irradiation with a single light source. Angewandte Chemie International Edition 53 7163#7168 (2014.
#Nanoparticles break the symmetry of light How can a beam of light tell the difference between left and right?
Instead, the light can be directed either to the left or to the right. This has become possible by employing a remarkable physical effect the spin-orbit coupling of light.
This new kind of optical switch has the potential to revolutionize nanophotonics. The researchers have published now their work in the journal Science.
this light is emitted not just into one direction.""A particle in free space will always emit as much light into one particular direction as it emits into the opposite direction,
The incident laser light determines whether the light emitted by the particle travels left or right in the glass fibre.
Bicycles and Airplane propellers This is only possible because light has an intrinsic angular momentum, the spin. Similar to a pendulum which can swing in one particular plane
"Usually, the light oscillates in a plane perpendicular to its direction of propagation. If the oscillation is circular,
It is exactly the same with the beams of light in the ultra-thin glass fibre.
When a particle that is coupled to the glass fibre is irradiated with a laser in such a way that it emits light of a particular sense of rotation,
the emitted light will thus propagate into just one particular direction inside the glass fibre either to the left or to the right.
Both the diameter of the fibre and the particle are even smaller than the wavelength of the emitted light."
"The method could be applied to integrated optical circuits. Such systems may one day replace the electronic circuits we are using today
The emitters like most nanoscale silicon devices were produced through photolithography a process in which patterns are transferred optically to layers of materials deposited on silicon wafers;
Velsquez-Garca believes that using arrays of emitters to produce nanodevices could have several advantages over photolithography the technique that produces the arrays themselves.
earlier the group developed the Pulsed laser deposition technique (PLD)# for this building the materials one atomic layer at a time.
The solution that UT researchers publish in Advanced Functional Materials is combining PLD with so-called soft lithography.
Kim also made his nanosheets responsive to near-infrared light a wavelength of light that is harmless to humans.
Depending on the shape of the nanosheet the near-infrared radiation bounces back with a different wavelength.
The narrower the band of absorbed light is the more sensitive the biosensor. Currently plasmonic absorbers used in biosensors have a resonant bandwidth of 50 nanometers said Koray Aydin assistant professor of electrical engineering and computer science at Northwestern University's Mccormick School of engineering and Applied science.
Aydin and his team have created a new nanostructure that absorbs a very narrow spectrum of light#having a bandwidth of just 12 nanometers.
The absorption of light is also high exceeding 90 percent at visible frequencies. Aydin said this design can also be used in applications for photothermal therapy thermophotovoltaics heat-assisted magnetic recording thermal emission and solar-steam generation.
heated the surface with a laser beam, and then recorded the temperature evolution of the sample."
when the radius of the laser beam used to heat the metal coated crystals was above ten microns,
#Blades of grass inspire advance in organic solar cells Using a biomimicking analog of one of nature's most efficient light-harvesting structures blades of grass an international research team led by Alejandro Briseno of the University of Massachusetts Amherst
has taken a major step in developing long-sought polymer architecture to boost power-conversion efficiency of light to electricity for use in electronic devices.
and like grass blades they are particularly effective at converting light to energy. The advance not only addresses the problem of dead ends or discontinuous pathways that make for inefficient energy transfer
#Nanotube cathode beats large pricey laser Scientists are a step closer to building an intense electron beam source without a laser.
that completely eliminates the need for a room-sized laser system. Tests with the nanotube cathode have produced beam currents a thousand to a million times greater than the one generated with a large pricey laser system.
The technology has extensive applications in medical equipment and national security since an electron beam is a critical component in generating X-rays.
Traditionally accelerator scientists use lasers to strike cathodes in order to eject electrons through photoemission. The electric and magnetic fields of the particle accelerator then organize the electrons into a beam.
The tested nanotube cathode requires no laser: it only needs the electric field already generated by an accelerator to siphon the electrons off a process dubbed field emission n
It should absorb virtually all wavelengths of light that reach Earth's surface from the sun but not much of the rest of the spectrum since that would increase the energy that is reradiated by the material
The material is a two-dimensional metallic dielectric photonic crystal and has the additional benefits of absorbing sunlight from a wide range of angles
Most of the sun's energy reaches us within a specific band of wavelengths Chou explains ranging from the ultraviolet through visible light and into the near-infrared.
The material is made from a collection of nanocavities and you can tune the absorption just by changing the size of the nanocavities Chou says.
Another key characteristic of the new material Chou says is that it is matched well to existing manufacturing technology.
-and angle-resolved photoelectron spectroscopy technique to identify such valleys in the band structure of an ultrathin layer of molybdenum disulfide just a few atoms thick.
#Controlling photoluminescence with silicon nanophotonics for better devices Silicon nanowires have a great deal of potential in future high-performance electronic sensing and energy devices.
Particle size and chemical composition are determined by dynamic light scattering, analytical centrifugation, electron microscopy and inductively coupled plasma mass spectrometry (ICP-MS),
or less fluoresce under ultraviolet light. Because of this property silicon nanoparticles may one day serve as easily detectable"tags"for tracking nanosized substances in biological, environmental or other dynamic systems s
Novel applications of'quantum dots'including lasers biological markers qubits for quantum computing and photovoltaic devices arise from the unique optoelectronic properties of the QDS
when irradiated with light or under external electromagnetic fields. Our main interest in QDS is for the fabrication of high efficiency solar cells says Yamaguchi.
The resulting external quantum efficiency of these solar cell structures in the 900 to 1150 nm wavelength range was higher than devices with the QD layer.
and light sources thanks to the unprecedented properties it offers: very low electrical resistance high thermal conductivity and mechanically stretchable yet harder than diamond.
However unlike graphene TMDCS can also emit light allowing applications such as photodetectors and light emitting devices to be manufactured.
Until recently fabrication of TMDCS such as Mos2 has been difficult as most techniques produce only flakes typically just a few hundred square microns in area.
#Single unlabelled biomolecules can be detected through light Being able to track individual biomolecules and observe them at work is every biochemist's dream.
Researchers at the Max Planck Institute for the Science of Light have taken a big step closer to this goal.
they have amplified the interaction of light with DNA to the extent that they can now track interactions between individual DNA molecule segments.
Although light can be used to detect unlabelled biomolecules, the approach cannot be used to detect single DNA molecules,
A team of physicists headed by Frank Vollmer of the Laboratory for Nanophotonics and Biosensors at the Max Planck Institute for the Science of Light has succeeded now in amplifying the interaction of light with DNA molecules to the extent that their photonic biosensor can be used to observe single unlabelled molecules and their interactions.
A microsphere becomes an optical whispering gallery To achieve this, the physicists use glass beads around 60 micrometres in diameter, about the thickness of a human hair,
The microsphere and nanowire amplify the interaction between light and molecules. With the help of a prism, the researchers shine laser light into the microsphere.
The light is reflected repeatedly at the internal surface of the sphere until, ultimately, it propagates along the inside surface,
similar to the way sound waves travel along the walls of a circular enclosure or whispering gallery: when someone whispers at one end of the domed or vaulted gallery,
If a molecule is fixed to the surface of the glass bead, the light beam travels past it more than a hundred thousand times.
This interaction is amplified greatly due to the frequent contact between the light and the molecule. However
The light whizzing past generates plasmons: collective oscillations of electrons.""The plasmons pull the light wave a little further out of the glass microsphere,
"Vollmer explains. This amplifies the field strength of the light wave by a factor of more than a thousand.
the wavelength of the light shifts and is amplified by the microsphere and nanowire. This shift can be measured.
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