At its most basic level, your smart phone's battery is powering billions of transistors using electrons to flip on and off billions of times per second.
But if microchips could use photons instead of electrons to process and transmit data, computers could operate even faster.
the free electrons on its surface begin to oscillate together in a wave. These oscillations create their own light,
which reacts again with the free electrons. Energy trapped on the surface of the nanocube in this fashion is called a plasmon.
For the present demonstration, the researchers had to use a laser light to pump electrons to emit light.
2015ultra-thin nanowires can trap electron'twisters'that disrupt superconductors February 24th, 2015simulating superconducting materials with ultracold atoms:
and electron transport at the nanometer scale. Professor Cronin's research spans a broad range of topics including electrical and spectroscopic characterization of carbon nanotubes, graphene,
and electron energy loss spectroscopy (EELS) are used to follow the effects of the plasma treatments on a range of samples having different numbers of layers.
The electrical mobility of a material is a measure of how easily electrons can travel across its surface.
hydrogen gas that has been electrified to separate the electrons from the protons--to remove the copper oxide at much lower temperatures.
and air molecules in the chamber's atmosphere generates cyano radicals--carbon-nitrogen molecules that have been stripped of their electrons.
The Sub-ngstrm Low Voltage Electron (SALVE) microscope should improve contrast and reduce damage on biomolecules and two-dimensional nanomaterials, such as graphene March 18th,
The Sub-ngstrm Low Voltage Electron (SALVE) microscope should improve contrast and reduce damage on biomolecules and two-dimensional nanomaterials, such as graphene March 18th, 2015news and information 30 years after C60:
The Sub-ngstrm Low Voltage Electron (SALVE) microscope should improve contrast and reduce damage on biomolecules and two-dimensional nanomaterials, such as graphene March 18th,
2015ultra-thin nanowires can trap electron'twisters'that disrupt superconductors February 24th, 2015discoveries Quantum computing: 1 step closer with defect-free logic gate-Developing a new approach to quantum computing, based on braided quasiparticles as a logic gate to speed up computing,
An international team of researchers has used infinitely short light pulses to observe ultrafast changes in the electron-level properties of superconductors, setting a new standard for temporal resolution in the field.
whether the electron interactions occurring inside the materials are direct and instantaneous, or mediated by some delayed interaction.
The snap-shot observations, detailed this week in Nature Physics, support the hypothesis that electron interactions are delayed
and mediated by their interaction with the spin and magnetic pull of other electrons. The process took only 10 femtoseconds--something that
Few studies explore toxicity of cellulose nanocrystals March 10th, 2015superconductivity Electrons in slow motion: Here's how to see the'fastest slow process'--to understand superconductors March 9th, 2015strength in numbers:
which involves a material giving up electrons and transporting ions through another material at the interface between electrode and electrolyte.
"Moreover, the conductive Fe-Ni core provides a highway to accelerate the transport of electrons to the current collector,
and shuttle data with light instead of electrons. Electrical and computer engineering associate professor Rajesh Menon and colleagues describe their invention today in the journal Nature Photonics.
"But that information has to be converted to electrons when it comes into your laptop. In that conversion, you're slowing things down.
the photons of light must be converted to electrons before a router or computer can handle the information.
And because photonic chips shuttle photons instead of electrons, mobile devices such as smartphones or tablets built with this technology would consume less power,
and Kazuo Takimiya of the RIKEN Center for Emergent Matter Science managed to create a type of polymer solar cell called a bulk-heterojunction solar cellhere the electron donor
an orientation well suited to the transport of electron holes through the material. Takamiya says,
and thereby control the electron density in the film. By employing this method, the researchers have succeeded in converting non-superconducting multilayer Fese films into high-Tc superconductors with Tc as high as 50 K. The present result gives a great impact to both the basic
closely approaching the temperature of liquid nitrogen (77 K). The present report would lead to intensive researches to further increase Tc by changing the number of atomic layers, the amount of doped electrons and the species of substrate.
it is absorbed by electrons in the gold arms. The arms are so thin that the electrons are forced to move along the spiral.
Electrons that are driven toward the center absorb enough energy so that some of them emit blue light at double the frequency of the incoming infrared light."
"This is similar to what happens with a violin string when it is bowed vigorously, "said Stevenson Professor of Physics Richard Haglund,
The electrons at the center of the spirals are driven pretty vigorously by the laser's electric field.
because the polarization pushes the electrons toward the center of the spiral. Counterclockwise polarized light
because the polarization tends to push the electrons outward so that the waves from all around the nano-spiral interfere destructively.
So far, Davidson has experimented with small arrays of gold nano-spirals on a glass substrate made using scanning electron-beam lithography.
Due to the weak electron-phonon coupling in graphene, 2d Dirac massless carriers can present a much more elevated temperature than the graphene lattice.
"In our study, we make use of the fact that a heat current passing through a magnetic material creates a separation of electron spins.
Spin transfer torque is the transfer of the spin angular momentum from conduction electrons to the magnetization of a ferromagnet
The spin-dependent Seebeck effect refers to the analogous phenomenon involving the spin of electrons in a ferromagnet."
This is necessary because materials are susceptible to being destroyed by the high energy electron beam that is used to image them.
The article is titled"Surface Determination through Atomically Resolved Secondary Electron Imaging.""Other co-authors are Hamish Brown, Adrian D'Alfonso, Pratik Koirala, Colin Ophus, Yuyuan Lin, Yuya Suzuki, Hiromi Inada, Yimei Zhu, Les Allen,
and bulk atoms simultaneously, retaining much of the surface sensitivity of traditional SEM through secondary electrons.
Secondary electrons are the result of a highly energized beam of electrons striking a material
and causing atoms in the material to emit energy in the form of electrons rather than photons.
As a large portion of secondary electrons are emitted from the surface of a material in addition to its bulk they are good resources for obtaining information about atomic surface structure.
"Existing secondary electron image simulation methods had to be extended to take into account contributions from valence orbitals in the material,
These experiments were coupled with careful secondary electron image simulations, density functional theory calculations, and aberration-corrected high resolution transmission electron microscopy."
In graphene, infrared light launches ripples through the electrons at the surface of this metallike material called surface plasmon polaritons that the researchers were able to control using a simple electrical circuit.
#X-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions A team of scientists used a newly developed reaction chamber to combine x-ray absorption spectroscopy and electron microscopy for an unprecedented portrait of a common chemical reaction.
a focused electron beam passes through the sample and captures images of the nanoparticles within.
and complementary x-ray and electron probe techniques over time. NSLS ended its 32-year experimental run in the fall of 2014,
If free electrons or other substances could travel through the electrolyte, they would short circuit the current in the fuel cell
Electrochemists have spent many years in a continuing search for newer, more highly conducting (ions and not electrons) and a more electrochemically stable electrolyte system.
2015x-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th,
2015chemistry X-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th,
2015x-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th, 2015announcements June 29th, 2015efforts to Use Smart Nanocarriers to Cure Leukemia Yield Promising
2015x-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th, 2015energy June 29th, 2015making new materials with micro-explosions:
2015x-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th,
2015fuel Cells X-rays and electrons join forces to map catalytic reactions in real-time: New technique combines electron microscopy and synchrotron X-rays to track chemical reactions under real operating conditions June 29th, 2015buckle up for fast ionic conduction June 16th, 2015a protective shield for sensitive catalysts:
Due to their different configurations of electrons, these tetrahedra become elongated along the crystallographic c-axis for nickel,
However, so far only electron holography could be considered for mapping magnetic domains of three-dimensional objects at the nanometre scale.
instead depends upon the uncanny ability of gold atoms to trap silicon-carrying electrons to selectively prevent the etching.
In this study, researchers first pattern nanostructures on the graphene surface by bombarding it with electron beams and etching it with oxygen ions.
the electrons in graphene nanostructures begin to oscillate. This phenomenon concentrates light into tiny spots,
Making graphene's electrons oscillate in different ways makes it possible to"read"all the vibrations of the molecule on its surface."
as supported by electron energy loss spectroscopy (EELS) measurements and also by the fact that no anelastic behaviour could be observed under tension.
Caltech researchers adopted a novel technique, ultrafast electron crystallography (UEC), to visualize directly in four dimensions the changing atomic configurations of the materials undergoing the phase changes.
"To study this, the researchers used their technique, ultrafast electron crystallography. The technique, a new development--different from Zewail's Nobel prize-winning work in femtochemistry, the visual study of chemical processes occurring at femtosecond scales--allowed researchers to observe directly the transitioning atomic configuration of a prototypical phase-change
followed by a pulse of electrons. The laser pulse causes the atomic structure to change from the crystalline to other structures
Then, when the electron pulse hits the sample, its electrons scatter in a pattern that provides a picture of the sample's atomic configuration as a function of the time.
and could be important for future device technologies as well as for fundamental studies of electron transport in molecular nanostructures.
In atomic-scale transistors, this current is extremely sensitive to single electrons hopping via discrete energy levels.
Single-electron transport in molecular transistors has been studied previously using top-down approaches, such as lithography and break junctions.
single electrons can tunnel between template and tip by hopping via nearly unperturbed molecular orbitals,
In our case, the charged atoms nearby provide the electrostatic gate potential that regulates the electron flow
and orientation has a dramatic effect on the electron flow across the molecule, manifested by a large conductance gap at low bias voltages.
which relocates the electrons from a dark state to a luminescent state, thereby increasing the material ability to convert electrons into light particles, or photons.
With this technique, the multilayer Mos2 semiconductors are at least as efficient as monolayer ones. Duan team is currently moving forward to apply this approach to similar materials,
carrying electrons with almost no resistance even at room temperature, a property known as ballistic transport. Graphene's unique optical, mechanical and electrical properties have lead to the one-atom-thick form of carbon being heralded as the next generation material for faster, smaller, cheaper and less power-hungry electronics."
Plasmonics study suggests how to maximize production of'hot electrons'Abstract: New research from Rice university could make it easier for engineers to harness the power of light-capturing nanomaterials to boost the efficiency
including metallic nanoparticles that convert light into plasmons, waves of electrons that flow like a fluid across the particles'surface.
or nanostructure is that you can excite some subset of electrons in the metal to a much higher energy level,
"Scientists call these'hot carriers'or'hot electrons.'"'"Halas, Rice's Stanley C. Moore Professor of Electrical and Computer engineering and professor of chemistry, bioengineering, physics and astronomy,
and materials science and nanoengineering, said hot electrons are particularly interesting for solar-energy applications because they can be used to create devices that produce direct current
"He and Halas said Manjavacas, a theoretical physicist in the group of LANP researcher Peter Nordlander, conducted work in the new study that offers a fundamental insight into the underlying physics of hot-electron-production
"From this perspective, one can determine the total number of electrons produced, but it provides no way of determining how many of those electrons are actually useful, high-energy, hot electrons,
"Manjavacas said. He said Zheng's data allowed a deeper analysis because his experimental setup selectively filtered high-energy hot electrons from their less-energetic counterparts.
To accomplish this, Zheng created two types of plasmonic devices. Each consisted of a plasmonic gold nanowire atop a semiconducting layer of titanium dioxide.
and allowed only hot electrons to pass from the gold to the semiconductor. The second setup allowed all electrons to pass."
"The experiment clearly showed that some electrons are hotter than others, and it allowed us to correlate those with certain properties of the system,
"Manjavacas said.""In particular, we found that hot electrons were correlated not with total absorption. They were driven by a different, plasmonic mechanism known as field-intensity enhancement."
"LANP researchers and others have spent years developing techniques to bolster the field-intensity enhancement of photonic structures for single-molecule sensing and other applications.
Zheng and Manjavacas said they are conducting further tests to modify their system to optimize the output of hot electrons.
the resulting increase in length and decrease in cross-sectional area restricts the flow of electrons through the material.
because electrons can travel over such a hierarchically buckled sheath as easily as they can traverse a straight sheath."
The asymmetry of a p-n junction presents the electrons with an"on/off"transport environment.
"Electron flow at molecular length-scales is dominated by quantum tunneling, "Neaton explains.""The efficiency of the tunneling process depends intimately on the degree of alignment of the molecule's discrete energy levels with the electrode's continuous spectrum.
in nearly perfect alignment with the Fermi electron energy levels of the gold electrodes. Symmetry was broken by a substantial difference in the size of the area on each gold electrode that was exposed to the ionic solution.
The bilayer structure blocks the injection of electrons into the sol-gel material providing low leakage current, high breakdown strength and high energy extraction efficiency."
and shuttle data with light instead of electrons. Electrical and computer engineering associate professor Rajesh Menon and colleagues describe their invention today in the journal Nature Photonics Silicon photonics could significantly increase the power and speed of machines such as supercomputers
"But that information has to be converted to electrons when it comes into your laptop. In that conversion, you're slowing things down.
the photons of light must be converted to electrons before a router or computer can handle the information.
And because photonic chips shuttle photons instead of electrons, mobile devices such as smartphones or tablets built with this technology would consume less power,
which ions and electrons must rapidly move. Researchers have built arrays of nanobatteries inside billions of ordered,
and electrons can do their job in such ultrasmall environments. Up to a billion of these nanopore batteries could fit in a grain of sand.
The nanobatteries were fabricated by atomic layer deposition to make oxide nanotubes (for ion storage) inside metal nanotubes for electron transport, all inside each end of the nanopores.
and out and close contact between the thin nested tubes to ensure fast transport for both ions and electrons.
and electron transport in nanostructures for energy storage and to test the limits of 3-D nanobattery technology y
and gaining a previously unattainable understanding of processes such as electron, water or ion transport or chemical reactions.
and its physical characteristics are determined by the complex interactions between atoms and electrons. Theoreticians use quantum mechanics to calculate the forces between atoms,
and the behaviour of electrons in materials. Specifically, first-principles simulations are based on quantum mechanics, and are a powerful technique widely used to uncover diverse properties of matter and materials at the atomic scale.
#Exciton, exciton on the wall Researchers have observed, in metals for the first time, transient excitons the primary response of free electrons to light.
Here, the researchers discovered that the surface electrons of silver crystals can maintain the excitonic state more than 100 times longer than for the bulk metal,
the light shakes the metals free electrons and the resulting acceleration of electrons creates a nearly perfect replica of the incident light providing a reflection.
Excitons, or particles of the light-matter interaction where light photons become temporarily entangled with electrons in molecules
This discovery sheds light on the primary excitonic response of solids which could allow quantum control of electrons in metals, semiconductors,
It also potentially allows for the generation of intense femotosecond electron pulses that could increase resolution for time-resolved electron microscopes that follow the motion of individual atoms
it is absorbed by electrons in the gold arms. The arms are so thin that the electrons are forced to move along the spiral.
Electrons that are driven toward the center absorb enough energy so that some of them emit blue light at double the frequency of the incoming infrared light.
This is similar to what happens with a violin string when it is bowed vigorously, said Stevenson Professor of Physics Richard Haglund,
The electrons at the center of the spirals are driven pretty vigorously by the lasers electric field.
because the polarization pushes the electrons toward the center of the spiral. Counterclockwise polarized light,
because the polarization tends to push the electrons outward so that the waves from all around the nano-spiral interfere destructively.
So far, Davidson has experimented with small arrays of gold nano-spirals on a glass substrate made using scanning electron-beam lithography.
which half of the electronic states that can contribute to the material electrical conductivity are occupied by electrons,
because electrons can freely travel around by moving in and out of the empty sites. In this organic material,
however, strong repulsion between the electrons in the full and empty states suppresses free movement.
triangular patterns (Fig. 1) removes the freedom of the electrons'spin such that the molecules line up
The only way for electrons to break free is to forcefully add additional electrical charge to the system,
and manage digital information by using the spin of electrons. Metal complexes showing spin-transition (i e. reversible interconversion between different isomers) are among the best candidates for the preparation of molecular memories and spintronic devices.
A short time after excitation, the initial excitation of Argon's eighteen electrons (blue spheres) is observed at several places within cluster.
At longer times after excitation, many excited electrons are see escaping the cluster in all directions.
The x-ray electron-free laser (XFEL) is the perfect example of new technology and old perceptions converging on that narrow boundary between science and science fiction.
when x-ray photons collide with the electrons of a target samplea specific atom or enzyme molecule, for instanceand scatter.
there emerges the information necessary to detect the electron locations of the sample before it was irradiated,
The photon/electron collisions create infinite and simultaneous quantum reactions, where electrons emerge and disappear and new particles propagate,
all of them creating those frantic lines etched on the detectors. To read between the lines, quite literally, Young
MC incorporates detailed information from quantum mechanics to simulate the interactions between the electrons and the XFEL pulses.
with an end goal of mapping the electron pathways created by XFEL bursts. According to Young, small bursts produce very high-resolution scattering patterns,
#Hematite're-growth'smoothes rough edges for clean energy harvest (Nanowerk News) Finding an efficient solar water splitting method to mine electron-rich hydrogen for clean
Tunneling electrons from a scanning tunneling microscope tip excites phonons in graphene. The image shows the graphene lattice with blue arrows indicating the motion direction of that carbon atoms for one of the low energy phonon modes in graphene.
issue of Physical Review Letters("Strong Asymmetric Charge Carrier Dependence in Inelastic Electron Tunneling Spectroscopy of Graphene Phonons").
One way to measure these tiny vibrations is to bounce electrons off the material and measure how much energy the electrons have transferred to the vibrating atoms.
But it's difficult. The technique, called inelastic electron tunneling spectroscopy, elicits only a small blip that can be hard to pick out over more raucous disturbances."
"Researchers are faced frequently with finding ways to measure smaller and smaller signals, "says NIST researcher Fabian Natterer,
such as that supplied by the electrons in a scanning tunneling microscope (STM). To filter the phonons'signal from other distractions,
NIST researchers used their STM to systematically alter the number of electrons moving through their graphene device.
As the number of electrons were varied, the unwanted signals also varied in energy, but the phonons remained fixed at their characteristic frequency.
Averaging the signals over the different electron concentrations diluted the annoying disturbances, but reinforced the phonon signals.
which become filled with electrons and stop the phonons from vibrating when we switch from hole to electron doping."
"The team notes that this effect is similar to resonance-induced effects seen in small molecules.
and corresponding author of a paper describing this new analytical method in the journal Nature Communications("Surface Determination Through Atomically Resolved Secondary Electron Imaging").
and bulk atoms simultaneously, retaining much of the surface sensitivity of traditional SEM through secondary electrons.
Secondary electrons are the result of a highly energized beam of electrons striking a material
and causing atoms in the material to emit energy in the form of electrons rather than photons.
As a large portion of secondary electrons are emitted from the surface of a material in addition to its bulk they are good resources for obtaining information about atomic surface structure.
"Existing secondary electron image simulation methods had to be extended to take into account contributions from valence orbitals in the material,
These experiments were coupled with careful secondary electron image simulations, density functional theory calculations, and aberration-corrected high resolution transmission electron microscopy."
In photosynthesis, plants that are exposed to sunlight use carefully organized nanoscale structures within their cells to rapidly separate charges pulling electrons away from the positively charged molecule that is left behind,
The polymer donor absorbs sunlight and passes electrons to the fullerene acceptor; the process generates electrical energy.
because the electrons sometimes hop back to the polymer spaghetti and are lost. The UCLA technology arranges the elements more neatly like small bundles of uncooked spaghetti with precisely placed meatballs.
The fullerenes inside the structure take electrons from the polymers and toss them to the outside fullerene
which can effectively keep the electrons away from the polymer for weeks. When the charges never come back together,
This force causes an increasing percentage of electrons to start flowing in the rongdirection as the magnetic field is ramped up,
Superfast electrons cause extremely large magnetoresistance he faster the electrons in the material move, the greater the Lorentz force and thus the effect of a magnetic field, explains Binghai Yan, a researcher at the Max Planck Institute for Chemical Physics of Solids in Dresden.
and phosphorus. This material contains superfast charge carriers, known as relativistic electrons that move at around one thousandth the speed of light,
In the process, they discovered why the electrons are so fast and mobile. The material owes its exotic properties to unusual electronic states in niobium phosphide.
Some electrons in this material, known as a Weyl metal act as if they have no mass. As a result, they are able to move very rapidly.
Integrating high quality III-V materials on silicon is critical for getting the benefit of higher electron mobility to build transistors with improved power and performance for technology scaling at 7 nm and beyond.
The electrons necessary for this reaction travel through the external circuit, generating an electric current. A supercapacitor is similar to a battery in that it can generate and store electric current,
and process information promises huge gains in performance over today's electron-based devices. But getting there is proving challenging.
is that"the magnetic moment of each nucleus is tiny, roughly 1, 000 times smaller than that of an electron."
or electrons can easily randomize the direction of the nuclear spins. Extreme experimental conditions such as high magnetic fields and cryogenic temperatures(-238 degrees Fahrenehit and below) are required usually to get even a small number of spins to line up.
The electron spins in these color centers can be cooled readily optically and aligned, and this alignment can be transferred to nearby nuclei.
"The intricate way in which electrons are bound inside complex oxides means that any strain--stretching,
Professor Jim Williams, Professor Andrei Rode and Associate professor Jodie Bradbury with the complex electron diffraction patterns.
Using a combination of electron diffraction patterns and structure predictions, the team discovered the new materials have crystal structures that repeat every 12,
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