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Archive for: November

QDOT imagesLast month, Amazon released Kindle Fire HDX 7 — the first ever mobile device to feature a quantum-dot-enhanced display.

The 7″ display includes a Quantum Dot Enhancement Film (QDEF) produced by 3M in collaboration with Nanosys, Inc. Compared to the traditional LED-LCD display, the QDEF essentially replaces the YAG phosphor of the white LED backlight and functions as a high-efficiency photoluminescent emitter. The ODEF includes quantum dots of different sizes, which would emit different colors when excited due to quantum confinement effect. More detail of the QDEF can be found via the link below.

It is noted that the quantum-dot-enhanced display of Kindle Fire HDX 7 does not utilize the electroluminescent property of quantum dots, and thus is not actually a quantum dot light emitting diode (QLED). Nevertheless, it could signal the beginning of the mass commercialization of quantum dots technology in consumer markets.

And the “very best” of today’s display technologies according to Displaymate, quote,

“The very best of today’s display technologies? The Quantum Dots displays used in the Kindle Fire HDX 7 according to the report.

Quantum Dots are almost magical because they use Quantum Physics to produce highly saturated primary colors for LCDs that are similar to those produced by OLED displays. They not only significantly increase the size of the Color Gamut by 40-50 percent but also improve the power efficiency by an additional 15-20 percent. Instead of using White LEDs (which have yellow phosphors) that produce a broad light spectrum that makes it hard to efficiently produce saturated colors, Quantum Dots directly convert the light from Blue LEDs into highly saturated primary colors for LCDs. You can see the remarkable difference in their light spectra in Figure 4. Quantum Dots are going to revolutionize LCDs for the next 5+ years.”

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How does QDEF work?

Nanosys QDEF™ enables deep color and high efficiency by providing displays with an ideal light source. How does it do that?

Each sheet of QDEF contains trillions of tiny (by tiny we mean: a bit bigger than a water molecule but smaller than a virus in size) nanoscrystal phosphors, called “Quantum Dots .” Not found naturally occurring anywhere on Earth, these “dots” can be tuned, by changing their size, to emit light at just the right wavelengths for our displays and do so very efficiently.

Unlike conventional phosphor technologies such as YAG that emit with a fixed spectrum, quantum dots can actually convert light to nearly any color in the visible spectrum. Pumped with a blue source, such as the GaN LED, they can be made to emit at any wavelength beyond the pump source wavelength with very high efficiency (over 90% quantum yield) and with very narrow spectral distribution (only 30 – 40nm FWHM.) The real magic of quantum dots is in the ability to tune the color output of the dots, by carefully controlling the size of the crystals as they are synthesized so that their spectral peak output can be controlled within 2 nanometers to nearly any visible wavelength.

For the first time, display designers will have the ability to tune and match the backlight spectrum to the color filters. This means displays that are brighter, more efficient, and produce truly vibrant colors.

How does it all come together?

Engineering the quantum dots to precise display industry specifications isn’t enough to revolutionize the way LCDs are experienced on its own. The dots need to be easily integrated into current manufacturing operations with minimal impact on display system design if they are to be widely adopted. To do this, Nanosys spent a lot of time working with major display manufacturers to get the packaging just right so that it would be a simple, drop-in product that did not require any line retooling or process changes. The end result is called Quantum Dot Enhancement Film or QDEF.

Designed as a replacement for the an existing film in LCD backlights called the diffuser, QDEF combines red and green emitting quantum dots in a thin, optically clear sheet that emits white light when stimulated by blue (some of that blue is allowed to pass through to make the B in RGB at the LCM of course). So manufacturers who’ve invested billions in plant and equipment for LCD production can simply slip this sheet into their process, change their ‘white’ LEDs to blue (the same LEDs but without the phosphor) and start producing LCD panels with the colors and efficiencies of the best OLEDs, at a fraction of the cost and current industrial scale.

Nanosys is currently shipping production samples to display manufacturers and is on track to begin producing at commercial volumes fall of 2013.

shutterstock_113358130_sm(Nanowerk News) Jeong-Yeol Yoon, associate professor of agricultural and biosystems engineering, and Dr. Marvin Slepian, professor of cardiology and biomedical engineering, collaborated to test how nanotechnology-based techniques can be used to better facilitate adhesion between tissue and implanted devices.
“When we created the nanotexture surface, we thought it could be used as a sticky surface for the implants,” Yoon says.
Cell-substrate adhesion involves the interplay of mechanical properties, surface topographic features, electrostatic charge and biochemical mechanisms. By working at the nanoscale level, Yoon was able to maximize the physical properties of the underlying substrate in promoting adhesion.
But beyond simply creating a sticky surface, the researchers’ goal was to create a selectively sticky surface, favoring endothelial cell attachment, without favoring platelet attachment, Slepian says.
The connection between Yoon, a specialist in biosensors and nanotechnology from the College of Agriculture and Life Sciences, and Slepian, co-founder and chief scientific officer of artificial-heart manufacturer SynCardia, came about by chance. A graduate student in Yoon’s lab met Slepian through their shared interest in bicycling.
“It’s very rare for the agriculture people to work with the cardiovascular people in the medical school,” Yoon says.
But their research specialties clicked.
One particular challenge to overcome in cardiovascular implants is the potential for devices – such as stents placed inside coronary arteries – to become detached as a result of blood flow, Yoon says.
“We’re particularly focused on the cardiovascular applications because there’s a blood flow involved and our system is very good when there’s a flow situation,” Yoon says.
The results of the study, published in the journal Advanced Healthcare Materials (“Nanowell-Trapped Charged Ligand-Bearing Nanoparticle Surfaces: A Novel Method of Enhancing Flow-Resistant Cell Adhesion”), reveal that the researchers’ strategy leads to enhanced endothelial cell adhesion under both static and flow conditions.
The adhesive properties derive from optimized surface texturing, electrostatic charge and cell adhesive ligands (molecular binding substances) that are uniquely assembled on the substrata surface as an ensemble of nanoparticles trapped in nanowells.
“There are lot of other people out there who use nanotechnology for improving the implants, but this is stronger than other adhesive methods using nanotechnology,” Yoon says.
“Obviously it can be used for everything else – lungs, digestive track and other systems. There are lots of other opportunities we haven’t explored,” he says.
The research is a perfect fit for Advanced Healthcare Materials, a new journal that spun off from the longstanding Advanced Materials journal.
“The use of the materials for the health care applications is probably the hottest area in materials science and engineering,” Yoon says. “We believe the journal will become even stronger than the mother journal.”
Just as the new journal marks an exciting intersection of disciplines, Yoon says the environment at the UA encourages such interdisciplinary approaches.
“I joined the University of Arizona because there are so many interdisciplinary activities going on. I see a lot of collaboration between departments in the same college at other universities, but at the University of Arizona, the environment is more open and you see collaboration across colleges,” Yoon says.
Slepian agreed, saying the pair has already filed grant applications for future work together.
“It has been fun and exciting to have an interdisciplinary collaborator,” he says.
Source: University of Arizona

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201306047919620(Nanowerk News) Chemical engineers at Rice University have found a new catalyst that can rapidly break down nitrites, a common and harmful contaminant in drinking water that often results from overuse of agricultural fertilizers.
Nitrites and their more abundant cousins, nitrates, are inorganic compounds that are often found in both groundwater and surface water. The compounds are a health hazard, and the Environmental Protection Agency places strict limits on the amount of nitrates and nitrites in drinking water. While it’s possible to remove nitrates and nitrites from water with filters and resins, the process can be prohibitively expensive.
gold and palladium nanoparticles can rapidly break down nitrites
Researchers at Rice University’s Catalysis and Nanomaterials Laboratory have found that gold and palladium nanoparticles can rapidly break down nitrites.
“This is a big problem, particularly for agricultural communities, and there aren’t really any good options for dealing with it,” said Michael Wong, professor of chemical and biomolecular engineering at Rice and the lead researcher on the new study. “Our group has studied engineered gold and palladium nanocatalysts for several years. We’ve tested these against chlorinated solvents for almost a decade, and in looking for other potential uses for these we stumbled onto some studies about palladium catalysts being used to treat nitrates and nitrites; so we decided to do a comparison.”
Catalysts are the matchmakers of the molecular world: They cause other compounds to react with one another, often by bringing them into close proximity, but the catalysts are not consumed by the reaction.
In a new paper in the journal Nanoscale (“Supporting palladium metal on gold nanoparticles improves its catalysis for nitrite reduction “), Wong’s team showed that engineered nanoparticles of gold and palladium were several times more efficient at breaking down nitrites than any previously studied catalysts. The particles, which were invented at Wong’s Catalysis and Nanomaterials Laboratory, consist of a solid gold core that’s partially covered with palladium.
Over the past decade, Wong’s team has found these gold-palladium composites have faster reaction times for breaking down chlorinated pollutants than do any other known catalysts. He said the same proved true for nitrites, for reasons that are still unknown.
“There’s no chlorine in these compounds, so the chemistry is completely different,” Wong said. “It’s not yet clear how the gold and palladium work together to boost the reaction time in nitrites and why reaction efficiency spiked when the nanoparticles had about 80 percent palladium coverage. We have several hypotheses we are testing out now. “
He said that gold-palladium nanocatalysts with the optimal formulation were about 15 times more efficient at breaking down nitrites than were pure palladium nanocatalysts, and about 7 1/2 times more efficient than catalysts made of palladium and aluminum oxide.
Wong said he can envision using the gold-palladium catalysts in a small filtration unit that could be attached to a water tap, but only if the team finds a similarly efficient catalyst for breaking down nitrates, which are even more abundant pollutants than nitrites.
“Nitrites form wherever you have nitrates, which are really the root of the problem,” Wong said. “We’re actively studying a number of candidates for degrading nitrates now, and we have some positive leads.”
Source: Rice University

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Berkeley Lab Researchers Use Fluorescent Tetrapod Quantum Dots to Measure the Mechanical Strength of Polymer Fibers

QDOT images 3Fluorescent tetrapod nanocrystals could light the way to the future design of stronger polymer nanocomposites. A team of researchers with the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab) has developed an advanced opto-mechanical sensing technique based on tetrapod quantum dots that allows precise measurement of the tensile  strength of polymer fibers with minimal impact on the fiber’s mechanical properties.

In a study led by Paul Alivisatos, Berkeley Lab director and the Larry and Diane Bock Professor of Nanotechnology at the University of California (UC) Berkeley, the research team incorporated into polymer fibers a population of tetrapod quantum dots (tQDs) consisting of a cadmium-selenide (CdSe) core and four cadmium sulfide (CdS) arms. The tQDs were incorporated into the polymer fibers via electrospinning, among today’s leading techniques for processing polymers, in which a large electric field is applied to droplets of polymer solution to create micro- and nano-sized fibers. This is the first known application of electrospinning to tQDs.


Fluorescent tetrapod quantum dots or tQDs (brown) serve as stress probes that allow precise measurement of polymer fiber tensile strength with minimal impact on mechanical properties. Inserts show relaxed tQDs (upper) and stressed tQDs (lower).

“The electrospinning process allowed us to put an enormous amount of tQDs, up to 20-percent by weight, into the fibers with minimal effects on the polymer’s bulk mechanical properties,” Alivisatos says. “The tQDs are capable of fluorescently monitoring not only simple uniaxial stress, but stress relaxation and behavior under cyclic varying loads. Furthermore, the tQDs are elastic and recoverable, and undergo no permanent change in sensing ability even upon many cycles of loading to failure.”

Alivisatos is the corresponding author of a paper describing this research in the journal NANO Letters titledTetrapod Nanocrystals as Fluorescent Stress Probes of Electrospun Nanocomposites.” Coauthors were Shilpa Raja, Andrew Olson, Kari Thorkelsson, Andrew Luong, Lillian Hsueh, Guoqing Chang, Bernd Gludovatz, Liwei Lin, Ting Xu and Robert Ritchie.

From left, Andrew Olson, Shilpa Raja and Andrew Luong are members of Paul Alivisatos's research group who used electrospinning to incorporate tetrapod quantum dot stress probes into polymer fibers. (Photo by Roy Kaltschmidt)

From left, Andrew Olson, Shilpa Raja and Andrew Luong are members of Paul Alivisatos’s research group who used electrospinning to incorporate tetrapod quantum dot stress probes into polymer fibers. (Photo by Roy Kaltschmidt)

Polymer nanocomposites are polymers that contain fillers of nanoparticles dispersed throughout the polymer matrix. Exhibiting a wide range of enhanced mechanical properties, these materials have great potential for a broad range of biomedical and material applications. However, rational design has been hampered by a lack of detailed understanding of how they respond to stress at the micro- and nanoscale.

“Understanding the interface between the polymer and the nanofiller and how stresses are transferred across that barrier are critical in reproducibly synthesizing composites,” Alivisatos says. “All of the established techniques for providing this information have drawbacks, including altering the molecular-level composition and structure of the polymer and potentially weakening mechanical properties such as toughness. It has therefore been of considerable interest to develop optical luminescent stress-sensing nanoparticles and  find a way to embed them inside polymer fibers with minimal impact on the mechanical properties that are being sensed.”

The Berkeley Lab researchers met this challenge by combining semiconductor tQDs of CdSe/CdS, which were developed in an earlier study by Alivisatos and his research group, with electrospinning. The CdSe/CdS tQDs are exceptionally well-suited as nanoscale stress sensors because an applied stress will bend the arms of the tetrapods, causing a shift in the color of their fluorescence. The large electric field used in electrospinning results in a uniform dispersal of tQD aggregates throughout the polymer matrix, thereby minimizing the formation of stress concentrations that would act to degrade the mechanical properties of the polymer. Electrospinning also provided a much stronger bond between the polymer fibers and the tQDs than a previous diffusion-based technique for using tQDs as stress probes that was reported two years ago by Alivisatos and his group. Much higher concentrations of tQDs could also be a achieved with electrospinning rather than diffusion.

When stress was applied to the polymer nanocomposites, elastic and plastic regions of deformation were easily observed as a shift in the fluorescence of the tQDs even at low particle concentrations. As particle concentrations were increased, a  greater fluorescence shift per unit strain was observed. The tQDs acted as non-perturbing probes that tests proved were not adversely affecting the mechanical properties of the polymer fibers in any significant way.

“We performed mechanical tests using a traditional tensile testing machine with all of our types of polymer fibers,” says Shilpa Raja, a lead author of the Nano Letters paper along with Andrew Olson, both members of Alivisatos’ research group. “While the tQDs undoubtedly change the composition of the fiber – it is no longer pure polylactic acid but instead a composite – we found that the mechanical properties of the composite and crystallinity of the polymer phase show minimal change.”

The research team believes their tQD probes should prove valuable for a variety of biological, imaging and materials engineering applications.

“A big advantage in the development of new polymer nanocomposites would be to use tQDs to monitor stress build-ups prior to material failure to see how the material was failing before it actually broke apart,” says co-lead author Olson. “The tQDs could also help in the development of new smart materials by providing insight into why a composite either never exhibited a desired nanoparticle property or stopped exhibiting it during deformation from normal usage.”

For biological applications, the tQD is responsive to forces on the nanoNewton scale, which is the amount of force exerted by living cells as they move around within the body. A prime example of this is metastasizing cancer cells that move through the surrounding extracellular matrix. Other cells that exert force include the fibroblasts that help repair wounds, and cardiomyocytes, the muscle cells in the heart that beat.

“All of these types of cells are known to exert nanoNewton forces, but it is very difficult to measure them,” Raja says.

“We’ve done preliminary studies in which we have shown that cardiomyocytes on top of a layer of tQDs can be induced to beat and the tQD layer will show fluorescent shifts in places where the cells are beating. This could be extended to a more biologically-relevant environment in order to study the effects of chemicals and drugs on the metastasis of cancer cells.”

Another exciting potential application is the use of tQDs to make smart polymer nanocomposites that can sense when they have cracks or are about to fracture and can strengthen themselves in response.

“With our technique we are combining two fields that are usually separate and have never been combined on the nanoscale, optical sensing and polymer nanocomposite mechanical tunability,” Raja says. “As the tetrapods are incredibly strong, orders of magnitude stronger than typical polymers, ultimately they can make for stronger interfaces that can self-report impending fracture.”

This research was primarily supported by the DOE Office of Science.

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Lawrence Berkeley National Laboratory addresses the world’s most urgent scientific challenges by advancing sustainable energy, protecting human health, creating new materials, and revealing the origin and fate of the universe. Founded in 1931, Berkeley Lab’s scientific expertise has been recognized with 13 Nobel prizes. The University of California manages Berkeley Lab for the U.S. Department of Energy’s Office of Science. For more, visit

DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit the Office of Science website at


Additional Information

For more about the research of Paul Alivisatos go here

3D rendered Molecule (Abstract) with Clipping Path(Nanowerk News) Ben-Gurion University of the Negev  (BGU) researchers have developed an innovative process to convert carbon dioxide  and hydrogen into a renewable alternative for crude oil, which could transform  fuels used in gas and diesel-powered vehicles and jets.
The “green feed” crude oil can be refined into renewable liquid  fuels using established technologies and can be transported using existing  infrastructure to gas stations.  The highly efficient advance is made possible  in part using nanomaterials that significantly reduce the amount of energy  required in the catalytic process to make the crude oil.
“We can now use zero cost resources, carbon dioxide, water,  energy from the sun, and combine them to get real fuels,” said BGU’s Prof. Moti  Hershkowitz, presenting the new renewable fuel process at the Bloomberg Fuel  Choices Summit in Tel Aviv on November 13.  Carbon dioxide and hydrogen are two  of the most common elements available on earth.
“Ethanol (alcohol), biodiesel and/or blends of these fuels with  conventional fuels are far from ideal,” Hershkowitz explains. “There is a  pressing need for a game-changing approach to produce alternative, drop-in,  liquid transportation fuels by sustainable, technologically viable and  environmentally acceptable emissions processes from abundant, low-cost,  renewable materials.”
“BGU has filed the patents and we are ready to demonstrate and  commercialize it,” Hershkowitz says.  “Since there are no foreseen technological  barriers, the new process could become a reality within five to10 years,” he  adds.
The BGU crude oil process produces hydrogen from water, which is  mixed with carbon dioxide captured from external sources and synthetic gas  (syngas). This green feed mixture is placed into a reactor that contains a  nano-structured solid catalyst, also developed at BGU, to produce an organic  liquid and gas.
Prof. Moti Herskowitz is the Israel Cohen Chair in Chemical  Engineering and the vice president and dean of research and development at BGU.   He led the team that also includes Prof. Miron Landau, Dr. Roxana Vidruk and  others at BGU’s Blechner Center for Industrial Catalysis and Process  Development.
The Blechner Center, founded in 1995, has the infrastructure and  expertise required to deal with a wide variety of challenging topics related to  basic and applied aspects of catalysis and catalytic processes. This was  accomplished with major funding from various sources that include science  foundations, industrial partners and individual donors such as the lateNorbert  Blechner. Researchers at the Blechner Center have also developed a novel process  for converting vegetable and algae oils to advanced green diesel and jet fuels,  as well as a novel process for producing zero-sulfur diesel.
“Ben-Gurion University’s Blechner Center has been at the  forefront of alternative fuel research and development, working with major  American oil and automotive companies for more than 20 years,” says Doron  Krakow, executive vice president, American Associates, Ben-Gurion University of  the Negev.  “We applaud these new developments and BGU’s focus on giving the  world new technologies for more efficient, renewable fuel alternatives.”
Source: American Associates, Ben-Gurion University of the  Negev

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3D rendered Molecule (Abstract) with Clipping PathMenlo Park, Calif. — Researchers have made the first battery electrode that heals itself, opening a new and potentially commercially viable path for making the next generation of lithium ion batteries for electric cars, cell phones and other devices. The secret is a stretchy polymer that coats the electrode, binds it together and spontaneously heals tiny cracks that develop during battery operation, said the team from Stanford University and the Department of Energy’s (DOE) SLAC National Accelerator Laboratory.

They report the advance in the Nov. 19 issue of Nature Chemistry.



This prototype lithium ion battery, made in a Stanford lab, contains a silicon electrode protected with a coating of self-healing polymer. The cables and clips in the background are part of an apparatus for testing the performance of batteries during multiple charge-discharge cycles. (Brad Plummer/SLAC)


“Self-healing is very important for the survival and long lifetimes of animals and plants,” said Chao Wang, a postdoctoral researcher at Stanford and one of two principal authors of the paper. “We want to incorporate this feature into lithium ion batteries so they will have a long lifetime as well.”

Chao developed the self-healing polymer in the lab of Stanford Professor Zhenan Bao, whose group has been working on flexible electronic skin for use in robots, sensors, prosthetic limbs and other applications. For the battery project he added tiny nanoparticles of carbon to the polymer so it would conduct electricity.

”We found that silicon electrodes lasted 10 times longer when coated with the self-healing polymer, which repaired any cracks within just a few hours,” Bao said.

“Their capacity for storing energy is in the practical range now, but we would certainly like to push that,” said Yi Cui, an associate professor at SLAC and Stanford who led the research with Bao. The electrodes worked for about 100 charge-discharge cycles without significantly losing their energy storage capacity. “That’s still quite a way from the goal of about 500 cycles for cell phones and 3,000 cycles for an electric vehicle,” Cui said, “but the promise is there, and from all our data it looks like it’s working.”

Researchers worldwide are racing to find ways to store more energy in the negative electrodes of lithium ion batteries to achieve higher performance while reducing weight. One of the most promising electrode materials is silicon; it has a high capacity for soaking up lithium ions from the battery fluid during charging and then releasing them when the battery is put to work.

But this high capacity comes at a price: Silicon electrodes swell to three times normal size and shrink back down again each time the battery charges and discharges, and the brittle material soon cracks and falls apart, degrading battery performance. This is a problem for all electrodes in high-capacity batteries, said Hui Wu, a former Stanford postdoc who is now a faculty member at Tsinghua University in Beijing, the other principal author of the paper.

To make the self-healing coating, scientists deliberately weakened some of the chemical bonds within polymers – long, chain-like molecules with many identical units. The resulting material breaks easily, but the broken ends are chemically drawn to each other and quickly link up again, mimicking the process that allows biological molecules such as DNA to assemble, rearrange and break down.

Watch Video on YouTube Here:

To show how flexible their self-healing polymer is, researchers coated a balloon with it and then inflated and deflated the balloon repeatedly, mimicking the swelling and shrinking of a silicon electrode during battery operation. The polymer stretches but does not crack. (Brad Plummer/SLAC)

Researchers in Cui’s lab and elsewhere have tested a number of ways to keep silicon electrodes intact and improve their performance. Some are being explored for commercial uses, but many involve exotic materials and fabrication techniques that are challenging to scale up for production.

The self-healing electrode, which is made from silicon microparticles that are widely used in the semiconductor and solar cell industries, is the first solution that seems to offer a practical road forward, Cui said. The researchers said they think this approach could work for other electrode materials as well, and they will continue to refine the technique to improve the silicon electrode’s performance and longevity.

The research team also included Zheng Chen and Matthew T. McDowell of Stanford. Cui and Bao are members of the Stanford Institute for Materials and Energy Sciences, a joint SLAC/Stanford institute. The research was funded by DOE through SLAC’s Laboratory Directed Research and Development program and by the Precourt Institute for Energy at Stanford University.

SLAC is a multi-program laboratory exploring frontier questions in photon science, astrophysics, particle physics and accelerator research. Located in Menlo Park, California, SLAC is operated by Stanford University for the U.S. Department of Energy Office of Science. To learn more, please visit

The Stanford Institute for Materials and Energy Sciences (SIMES) is a joint institute of SLAC National Accelerator Laboratory and Stanford University. SIMES studies the nature, properties and synthesis of complex and novel materials in the effort to create clean, renewable energy technologies. For more information, please visit

DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit

Citation: C. Wang et al., Nature Chemistry, 17 October 2013 (10.1038/nchem.1802)

Scientists collaborate to maximize energy gains from tiny nanoparticles

“We are developing a new ‘micro-reactor’ that enables us to explore many aspects of catalytic function using multiple approaches at Brookhaven’s National Synchrotron Light Source (NSLS), the soon-to-be-completed NSLS-II, and the Center for Functional Nanomaterials (CFN),” said Stach, who works at the CFN.  “This approach lets us understand multiple aspects of how catalysts work so that we can tweak their design to improve their function. This work could lead to big gains in energy efficiency and cost savings for industrial processes.”  – Anatoly Frenkel, Yeshiva University

Sometimes big change comes from small beginnings. That’s especially true in the research of Anatoly Frenkel, a professor of physics at Yeshiva University, who is working to reinvent the way we use and produce energy by unlocking the potential of some of the world’s tiniest structures: nanoparticles.


“The nanoparticle is the smallest unit in most novel materials, and all of its properties are linked in one way or another to its structure,” said Frenkel. “If we can understand that connection, we can derive much more information about how it can be used for catalysis, energy, and other purposes.”

“This work could lead to big gains in energy efficiency and cost savings for industrial processes.”

— Eric Stach, CFN

Frenkel is collaborating with materials scientist Eric Stach and others at the U.S. Department of Energy’s Brookhaven National Laboratory to develop new ways to study how nanoparticles behave in catalysts—the “kick-starters” of chemical reactions that convert fuels to useable forms of energy and transform raw materials to industrial products.

“We are developing a new ‘micro-reactor’ that enables us to explore many aspects of catalytic function using multiple approaches at Brookhaven’s National Synchrotron Light Source (NSLS), the soon-to-be-completed NSLS-II, and the Center for Functional Nanomaterials (CFN),” said Stach, who works at the CFN.  “This approach lets us understand multiple aspects of how catalysts work so that we can tweak their design to improve their function. This work could lead to big gains in energy efficiency and cost savings for industrial processes.”

High-tech tools for science

Until now, the methods for understanding catalytic properties could only be used one at a time, with the catalyst ending up in a different state for each of the experiments. This made it difficult to compare information obtained using the different instruments. The new micro-reactor will employ multiple techniques—microscopy, spectroscopy, and diffraction—to examine different properties of catalysts simultaneously under operating conditions. By keeping particles in the same structural and dynamic state under the same reaction conditions, the micro-reactor will give scientists a much better sense of how they function.

nanoscale catalyst particles Click on the image to download a high-resolution version. This high-resolution transmission electron micrograph taken at the CFN reveals the arrangement of cerium oxide nanoparticles (bright angular “slashes” at the bottom of the image) supported on a titania substrate (background)‹a combination being explored as a catalyst for splitting water molecules to release hydrogen as fuel and for other energy-transformation reactions.


“These developments have resulted from the combination of unique facilities available at Brookhaven,” said Frenkel. “By working closely with Eric, we realized that there was a way to make both x-ray and electron-based methods work in a truly complementary fashion.

Each technique has strengths, Stach explained. “At the NSLS, using powerful beams of x-rays, we can tell how the entire group of nanoparticles behaves, while electron microscopy at the CFN lets us see the atomic structure of each nanoparticle.  By having both of these views of the catalysts we can more clearly understand the relationship between catalyst structure and function.”

Said Frenkel, “It was very satisfying for us to conduct the first tests with the reactor at each facility and receive positive results. I am particularly grateful to Ryan Tappero, the scientist who runs NSLS beamline X27A, for his expert help with x-ray data acquisition.”

Frenkel has had an ongoing collaboration with scientists at Brookhaven. Last year, with post-doctoral research associate Qi Wang, Frenkel and Stach measured properties of nanoparticles using the x-rays produced by the NSLS as well as atomic-scale imaging with electrons at the CFN. As reported in a paper published in the Journal of the American Chemical Society earlier this year, they discovered that rather than changing completely from one state to another at a certain temperature and size, as had been previously believed, there is a transition zone between states when particles are changing forms.

“This is of significance fundamentally because until now, the structures were known to merely change from one form to another—they were never envisioned to coexist in different forms,” Frenkel said. “With our information we can explain why catalysts often don’t work as expected and how to improve them.”

Training for young scientists

Anatoly Frenkel of Yeshiva University with students from Stern College for Women at the National Synchrotron Light Source at Brookhaven National Laboratory.


The collaboration also offers opportunities for students to experience the challenges of research, giving them access to the world-class tools at Brookhaven. Frenkel’s undergraduate students at Yeshiva University’s Stern College for Women help with measurements, data analysis, and interpretation, and many have already accompanied him to Brookhaven to assist in his work using NSLS and other cutting-edge instruments.

“I’m giving them firsthand experience about what a researcher’s life is like early on as they conduct first-rate research,” said Frenkel. “This experience opens doors to any field they want to be in.”

Alyssa Lerner, a pre-engineering major who has been working with Frenkel at Brookhaven, said the research “has helped me develop skills like computational analysis and critical thinking, which are essential in any scientific field. The hands-on experimental experience has given me a better understanding of how the scientific community operates, helping me make more informed career-related choices as I continue to advance my education.”

Pairing up students and mentors to advance education and making use of complementary imaging techniques to enhance energy efficiency—just two of the positive outcomes of this successful collaboration.

“By bringing together multiple complementary techniques to illuminate the same process we’re going to understand how nanomaterials work,” Frenkel said. “Ultimately, this research will create a better way of using, storing, and converting energy.”

The CFN and NSLS facilities at Brookhaven Lab are supported by the Department of Energy’s Office of Science. The collaborative work of Frenkel and Stach is funded by the Office of Science and Brookhaven’s Laboratory Directed Research and Development program.

The Center for Functional Nanomaterials is one of five DOE Nanoscale Science Research Centers (NSRCs), national user facilities for interdisciplinary research at the nanoscale, supported by the DOE Office of Science.  Together the NSRCs comprise a suite of complementary facilities that provide researchers with state-of-the-art capabilities to fabricate, process, characterize and model nanoscale materials, and constitute the largest infrastructure investment of the National Nanotechnology Initiative.  The NSRCs are located at DOE’s Argonne, Brookhaven, Lawrence Berkeley, Oak Ridge and Sandia and Los Alamos National Laboratories.  For more information about the DOE NSRCs, please visit

The National Synchrotron Light Source (NSLS) provides intense beams of infrared, ultraviolet, and x-ray light for basic and applied research in physics, chemistry, medicine, geophysics, and environmental and materials sciences.  Supported by the Office of Basic Energy Sciences within the U.S. Department of Energy, the NSLS is one of the world’s most widely used scientific facilities. For more information, visit

DOE’s Office of Science is the single largest supporter of basic research in the physical sciences in the United States, and is working to address some of the most pressing challenges of our time. For more information, please visit

This story incorporates content from a piece by Perel Skier on the Yeshiva University news blog.

green earth untitled(Nanowerk News) Researchers have created tiny protein  tubes named after the Roman god Janus which may offer a new way to accurately  channel drugs into the body’s cells.
Using a process which they liken to molecular Lego, scientists  from the University of Warwick and the University of Sydney have created what  they have named ‘Janus nanotubes’ – very small tubes with two distinct faces.  The study is published in the journal Nature Communications (“Janus cyclic peptide–polymer nanotubes”).
They are named after the Roman god Janus who is usually depicted  as having two faces, since he looks to the future and the past.
The Janus nanotubes have a tubular structure based on the  stacking of cyclic peptides, which provide a tube with a channel of around 1nm –  the right size to allow small molecules and ions to pass through.
Attached to each of the cyclic peptides are two different types  of polymers, which tend to de-mix and form a shell for the tube with two faces –  hence the name Janus nanotubes.
The faces provide two remarkable properties – in the solid  state, they could be used to make solid state membranes which can act as  molecular ‘sieves’ to separate liquids and gases one molecule at a time. This  property is promising for applications such as water purification, water  desalination and gas storage.
In a solution, they assemble in lipids bilayers, the structure  that forms the membrane of cells, and they organise themselves to form pores  which allow the passage of molecules of precise sizes. In this state they could  be used for the development of new drug systems, by controlling the transport of  small molecules or ions inside cells.
Sebastien Perrier of the University of Warwick said: “There is  an extraordinary amount of activity inside the body to move the right chemicals  in the right amounts both into and out of cells.
“Much of this work is done by channel proteins, for example in  our nervous system where they modulate electrical signals by gating the flow of  ions across the cell membrane.
“As ion channels are a key component of a wide variety of  biological process, for example in cardiac, skeletal and muscle contraction,  T-cell activation and pancreatic beta-cell insulin release, they are a frequent  target in the search for new drugs.
“Our work has created a new type of material – nanotubes – which  can be used to replace these channel processes and can be controlled with a much  higher level of accuracy than natural channel proteins.
“Through a process of molecular engineering – a bit like  molecular Lego – we have assembled the nanotubes from two types of building  blocks – cyclic peptides and polymers.
“Janus nanotubes are a versatile platform for the design of  exciting materials which have a wide range of application, from membranes – for  instance for the purification of water, to therapeutic uses, for the development  of new drug systems.”
Source: University of Warwick
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Printing Graphene Chips(Nanowerk News) Advanced plasma-based etching is a key  enabler of Moore’s Law that observes that the number of transistors on  integrated circuits doubles nearly every two years. It is the plasma’s ability  to reproduce fine patterns on silicon that makes this scaling possible and has  made plasma sources ubiquitous in microchip manufacturing.
A groundbreaking fabrication technique, based on what is called  a DC-augmented capacitively coupled plasma source, affords chip makers  unprecedented control of the plasma. This process enables DC-electrode borne  electron beams to reach and harden the surface of the mask that is used for  printing the microchip circuits. More importantly, the presence of the beam  creates a population of suprathermal electrons in the plasma, producing the  plasma chemistry that is necessary to protect the mask. The energy of these  electrons is greater than simple thermal heating could produce—hence the name  “suprathermal.” But how the beam electrons transform themselves into this  suprathermal population has been a puzzle.
Plasma Wave Spectrum
A  plasma wave can give rise to a population of suprathermal electrons. (Credit:  I.D. Kaganovich and D. Sydorenko)
Now a computer simulation developed at the U.S.  Department of Energy’s Princeton
Plasma Physics Laboratory in collaboration with the University  of Alberta has shed light on this transformation. The simulation reveals that  the initial DC-electrode borne beam generates intense plasma waves that move  through the plasma like ripples in water. And it is this beam-plasma instability  that leads to the generation of the crucial suprathermal electrons.
Understanding the role these instabilities play provides a first  step toward still-greater control of the plasma-surface interactions, and toward  further increasing the number of transistors on integrated circuits. Insights  from both numerical simulations and experiments related to beam-plasma  instabilities thus portend the development of new plasma sources and the  increasingly advanced chips that they fabricate.
55th Annual Meeting of the APS Division of Plasma  Physics
TO6.00005 Collisionless acceleration of plasma electrons by  intense electron beam
Session: Low Temperature Plasma Science, Engineering and  Technology
9:30 AM–11:06 AM, Thursday, November 14, 2013
Source: American Physical Society 

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(Nanowerk Spotlight) Cancer is one of the leading  causes of death in the world and remains a difficult disease to treat. Current  problems associated with conventional cancer chemotherapies include insolubility  of drugs in aqueous medium; delivery of sub-therapeutic doses to target cells;  lack of bioavailability; and most importantly, non-specific toxicity to normal  tissues. Recent contributions of nanotechnology research address possible  solutions to these conundrums. Nevertheless, challenges remain with respect to  delivery to specific sites, real time tracking of the delivery system, and  control over the release system after the drug has been transported to the  target site.

Nanomedical research on nanoparticles is exploring these issues  and has already been showing potential solutions for cancer diagnosis and  treatment. But a heterogeneous disease like cancer requires smart approaches  where therapeutic and diagnostic platforms are integrated into a theranostic  approach.

Theranostics – a combination of the words therapeutics and diagnostics – describes a treatment platform that combines a  diagnostic test with targeted therapy based on the test results, i.e. a step  towards personalized medicine. Making use of nanotechnology materials and  applications, theranostic nanomedicine can be understood as an integrated  nanotherapeutic system, which can diagnose, deliver targeted therapy and monitor  the response to therapy.

Theranostic nanomedicine has the potential for simultaneous and  real time monitoring of drug delivery, trafficking of drug and therapeutic  responses.

Our Smart Materials and Biodevice group at the Biosensors and Bioelectronics Centre, Linkoping University,  Sweden, has demonstrated for the first time a MRI-visual order-disorder micellar nanostructures for smart  cancer theranostics.

        drug release mechanism via functional outcome of pH response


The  drug release mechanism via functional outcome of the pH response illustrated in  the schematic diagram. (Image: Smart Materials and Biodevice group, Linköping  University)   In the report, we fabricated a novel pH-triggered tumour  microenvironment sensitive order-disorder nanomicelle platform for smart  theranostic nanomedicine.           

The real-time monitoring of drug distribution will help  physicians to assess the type and dosage of drug for each patient and thus will  prevent overdose that could result in detrimental side-effects, or suboptimal  dose that could lead to tumour progression.

Additionally, the monitoring of normal healthy tissues by  differentiating with the MRI contrast will help balance the estimation of lethal  dose (for normal tissue) and pharmacologically active doses (for tumour). As a  result, this will help to minimize off-target effects and enhance effective  treatment.

In the present report, the concurrent therapy by doxorubicin and  imaging strategies by superparamagnetic iron oxide nanoparticles with our smart  architecture will provide every detail and thus can enable stratification of  patients into categorized responder (high/medium/low), and has the potential to  enhance the clinical outcome of therapy.

It shows, for the first time, concentration dependent  T2-weighted MRI contrast for a monolayer of clustered cancer cells. The pH  tunable order-disorder transition of the core-shell structure induces the  relative changes in MRI that will be sensitive to tumour microenvironment and  stages.

  MRI visual order-disorder nanostructure for cancer nanomedicine A  novel MRI visual order-disorder nanostructure for cancer nanomedicine explores  pH-trigger mechanism for theranostics of tumour hallmark functions. The pH  tunable order-disorder transition induces the relative changes in MRI contrast.  The outcome elucidates the potential of this material for smart cancer  theranostics by delivering non-invasive real-time diagnosis, targeted therapy  and monitoring the course and response of the action. (Image: Smart Materials  and Biodevice group, Linköping University)  

Our findings illustrate the potential of these biocompatible  smart theranostic micellar nanostructures as a nontoxic, tumour-target specific,  tumour-microenvironment sensitive, pH-responsive drug delivery system with  provision for early stage tumour sensing, tracking and therapy for cells  over-expressed with folate receptors.

The outcomes elucidate the potential of  smart cancer theranostic nanomedicine in non-invasive real-time diagnosis,  targeted therapy and monitoring of the course and response of the action before,  during and after treatment regimen.                     

By Hirak K Patra, Nisar Ul Khali, Thobias Romu, Emilia  Wiechec, Magnus Borga, Anthony PF Turner and Ashutosh Tiwari, Biosensors and Bioelectronics Centre,  Linköping University, Sweden

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