Snapshots of the retarded interaction of charge carriers with ultrafast fluctuations in cuprates News and information High performance, lightweight supercapacitor electrodes of the future March 10th, 2015advantest to Exhibit at SEMICON China
Showcasing Broad Portfolio of Semiconductor Products, Technologies and Solutions March 10th, 2015are current water treatment methods sufficient to remove harmful engineered nanoparticle?
Understanding why a material's behavior changes as it gets smaller March 10th, 2015announcements High performance, lightweight supercapacitor electrodes of the future March 10th, 2015advantest to Exhibit at SEMICON China in Shanghai, China, March 17-19:
Showcasing Broad Portfolio of Semiconductor Products, Technologies and Solutions March 10th, 2015are current water treatment methods sufficient to remove harmful engineered nanoparticle?
2015the chameleon reorganizes its nanocrystals to change colors March 10th, 2015high performance, lightweight supercapacitor electrodes of the future March 10th,
2015quantum sensor's advantages survive entanglement breakdown: Preserving the fragile quantum property known as entanglement isn't necessary to reap benefits March 9th,
which could act as a more effective cathode--a fundamental electrode component of fuel cells from which positive current flows through an external circuit delivering electric power."
News and information High performance, lightweight supercapacitor electrodes of the future March 10th, 2015advantest to Exhibit at SEMICON China in Shanghai, China, March 17-19:
Showcasing Broad Portfolio of Semiconductor Products, Technologies and Solutions March 10th, 2015are current water treatment methods sufficient to remove harmful engineered nanoparticle?
Researcher Mohamed Elrawemi develops new technologies for defects in thin films, vital in products as printed electronics and solar panels February 24th,
Understanding why a material's behavior changes as it gets smaller March 10th, 2015announcements High performance, lightweight supercapacitor electrodes of the future March 10th, 2015advantest to Exhibit at SEMICON China in Shanghai, China, March 17-19:
Showcasing Broad Portfolio of Semiconductor Products, Technologies and Solutions March 10th, 2015are current water treatment methods sufficient to remove harmful engineered nanoparticle?
2015the chameleon reorganizes its nanocrystals to change colors March 10th, 2015high performance, lightweight supercapacitor electrodes of the future March 10th,
Researchers from Singapore and Qubec Team up to Develop Next-Generation Materials to Power Electronic devices and Electric vehicles February 28th,
#High performance, lightweight supercapacitor electrodes of the future Abstract: Researchers have developed a novel electrode to make low-cost, lightweight supercapacitors with superior performance,
a development that could mean faster charging time and longer battery life in electric vehicles and portable electronics.
As a novel energy storage device, supercapacitors have attracted substantial attention in recent years due to their ultra-high charge
and discharge rate, excellent stability, long cycle life and very high power density. Imagine charging your cell phone in just a few seconds or fueling up an electric car in but a few minutes,
which are both part of the promising future that supercapacitors could offer. Offsetting this promise is the fact that
while supercapacitors have the potential to charge faster and last longer than conventional batteries, they also need to be much larger in size
Thus, many scientists are working to develop green, lightweight, low-cost supercapacitors with high performance. Now two researchers from the S n. Bose National Centre for Basic Sciences, India, have developed a novel supercapacitor electrode based on a hybrid nanostructure made from a hybrid nickel oxide-iron oxide
exterior shell and a conductive iron-nickel core. In a paper published this week in the Journal of Applied Physics
from AIP Publishing, the researchers report the fabrication technique of the hybrid nanostructure electrode. They also demonstrate its superior performance compared to existing, non-hybrid supercapacitor electrodes.
Since nickel oxide and iron oxide are environmental friendly and cheap materials that are widely available in nature,
the novel electrode promises green and low-cost supercapacitors in future.""This hybrid electrode shows the superior electrochemical performance in terms of high capacitance the ability to store electrical charge of nearly 1415 farad per gram, high current density of 2. 5 ampere per gram,
low resistance and high power density,"said Ashutosh K. Singh, the primary researcher at the Department of Condensed Matter Physics and Material Sciences at the S n. Bose National Centre
the electrode could retain nearly 95 percent of initial capacitance after cycling or charging and discharging 3, 000 times."
"The Promise of Supercapacitors Supercapacitors are used electronic devices to store an extremely large amount of electrical charges.
They are also known as electrochemical capacitors, and they promise high power density, high rate capability, superb cycle stability and high energy density.
Conventional capacitors have high power density but low energy density, which means they can quickly charge
Supercapacitors are a bridge between conventional capacitors and batteries, combining the advantageous properties of high power, high energy density and low internal resistance,
reliable and potentially safer power source for electric and portable electronic devices in future, said Singh.
In supercapacitors, high capacitance, or the ability to store an electrical charge, is critical to achieve higher energy density.
How Scientists Built the New Electrode Inspired by previous research on improving conductivity via doping different metal oxide materials, Singh and Kalyan Mandal, another researcher and a professor at the S n. Bose
National Centre for Basic Sciences, mixed nickel oxide and iron oxide as a hybrid material and fabricated the novel core/shell nanostructure electrode."
"By changing the materials and morphologies of the electrode, one can manipulate the performance and quality of the supercapacitors,
"Singh said. In Singh's experiment, the core/shell hybrid nanostructure was fabricated through a two-step method.
He explained that supercapacitors store charges through a chemical process known as a redox reaction, which involves a material giving up electrons
and transporting ions through another material at the interface between electrode and electrolyte. Larger redox reaction surfaces are essential for achieving a higher power density for supercapacitors."
"Moreover, the conductive Fe-Ni core provides a highway to accelerate the transport of electrons to the current collector,
and electrochemical properties of the electrode, realizing high-performance supercapacitors,"Singh noted. How the New Electrode Performed Using techniques called cyclic voltammetry
and galvanostatic charge/discharge methods, Singh and Mandal studied the electrochemical properties of the hybrid material electrode.
Comparing with the counterpart, non-hybrid electrodes like nickel/nickel oxide and iron/iron oxide core/shell nanostructure electrodes, the hybrid material electrode demonstrated higher capacitance,
higher energy density and higher charging/discharging time.""For example, the current density of the hybrid electrode is three and 24 times higher than that of nickel/nickel oxide and iron/iron oxide electrodes, respectively,
"Singh said.""The comparative results show remarkable enrichment in the electrochemical activities of nickel/nickel oxide
and iron/iron oxide electrodes after combining them together, which suggests the hybrid electrode's better supercapacitive properties."
"One feature of Singh's fabrication technique is that it doesn't require extra binder materials.
According to Singh, binding materials are used commonly in the fabrication of carbon or graphene based supercapacitors for attaching redox active material on the current collector.
Without the mass of binding materials, the hybrid electrode is a good candidate to make lightweight supercapacitors."
"The remarkable electrochemical performances and material properties suggest that the iron oxide-nickel oxide hybrid core/shell nanostructure could be a reliable and promising candidate for fabricating the next generation lightweight, low-cost
and green supercapacitor electrodes for real life application, "Singh said. The researchers'next plan is to develop a whole supercapacitor device based on the hybrid electrode and test its functional performance,
a step closer to manufacturing production n
#Nanotechnology Helps Increasing Rate of Digital data Processing, Storage Iranian researchers proposed a new method based on nanotechnology to increase the rate of digital data processing and storage.
Quantum Cellular Automata (QCA) is one of the emerging technologies at nanometric scale for the production of future digital circuits.
Results of the research have been published in Microelectronics Journal vol. 46, issue 1, 2015, pp. 43-51 1
This led them to believe that Nano-85 itself was actually causing the VLPS to break apart.
#Microchip captures clusters of circulating tumor cells--NIH study Circulating tumor cells (CTCS) are cells that break away from a tumor and move through a cancer patient's bloodstream.
"The new technology--called Cluster-Chip--was developed with support from a Quantum Grant from NIBIB,
Toner and his collaborator Dr. Daniel Haber, M d.,Ph d.,also at MGH, recently used Cluster-Chip to capture
The chip is designed to slowly push blood through many rows of microscopic triangle-shaped posts.
and continue through the chip until reaching the next tip; however CTC clusters are left at the tip,
To determine the efficiency of Cluster-Chip, the researchers introduced fluorescently tagged cell clusters (ranging from 2-30 cells) into the chip
and counted the number of clusters that were captured and the number that flowed through undetected.
At a blood flow rate of 2. 5ml/hr, the chip captured 99 percent of clusters containing four or more cells, 70 percent of three-cell clusters,
Comparison of the clusters under a microscope before and after capture found that the chip had no negative effects on the integrity of the clusters as a whole.
The researchers next compared the efficiency of their novel chip to two currently-used methods that have had some success capturing CTC clusters.
the Cluster-Chip was significantly more efficient than a filter-based method, which pushes blood through a membrane with pores only large enough to let single cells pass through.
The chip was also more efficient than a different microfluidic chip--previously developed by Toner--that isolates CTCS
The results highlight the importance of the unique Cluster-Chip capture technique which is based on the structural properties of CTC clusters rather than their size or the presence of surface proteins.
This latter property makes the Cluster-Chip well-suited for capturing CTC clusters from a range of cancer types,
In this study, the chip captured CTC clusters in 11 of 27 (40.7 percent) breast cancer patients, 6 of 20 (30 percent) melanoma patients
"Toner anticipates that the Cluster-Chip will play an important role in stimulating new research on CTC cluster biology:"
By shrinking them down in size, researchers will be able to cram millions of these devices on a single chip.
and ultra-strong and lightweight structure, graphene has potential for many applications in electronics, energy, the environment,
An expert in biomaterials, Shah said 3-D printed graphene scaffolds could play a role in tissue engineering and regenerative medicine as well as in electronic devices.
so it could be used for biodegradable sensors and medical implants. Shah said the biocompatible elastomer
May 20th, 2015toward'green'paper-thin, flexible electronics May 20th, 2015globalfoundries Offers New Low-power 28nm Solution for High-performance Mobile and Iot Applications:
May 20th, 2015toward'green'paper-thin, flexible electronics May 20th, 2015globalfoundries Offers New Low-power 28nm Solution for High-performance Mobile and Iot Applications:
Researchers find a way of tuning light waves by pairing 2 exotic 2-D materials May 20th, 2015toward'green'paper-thin, flexible electronics May 20th, 2015organic nanoparticles
Keynote Speaker Dr. Doon Gibbs, Director of Brookhaven National Laboratory April 16th, 2015mit sensor detects spoiled meat:
Columbia Engineering researchers first to create a single-molecule diode--the ultimate in miniaturization for electronic devices--with potential for real-world applications Under the direction of Latha Venkataraman, associate professor of applied physics at Columbia Engineering,
researchers have designed a new technique to create a single-molecule diode, and, in doing so, they have developed molecular diodes that perform 50 times better than all prior designs.
Venkataraman's group is the first to develop a single-molecule diode that may have real-world technological applications for nanoscale devices.
Their paper,"Single-Molecule Diodes with High On-Off Ratios through Environmental Control""is published May 25 in Nature Nanotechnology."
"Our new approach created a single-molecule diode that has a high(>250) rectification and a high"on"current (0. 1 micro Amps),"says Venkataraman."
"Constructing a device where the active elements are only a single molecule has long been a tantalizing dream in nanoscience.
ever since its inception with Aviram and Ratner's 1974 seminal paper, represents the ultimate in functional miniaturization that can be achieved for an electronic device."
"With electronic devices becoming smaller every day, the field of molecular electronics has become ever more critical in solving the problem of further miniaturization,
The idea of creating a single-molecule diode was suggested by Arieh Aviram and Mark Ratner who theorized in 1974 that a molecule could act as a rectifier, a one-way conductor of electric current.
They have shown that single-molecules attached to metal electrodes (single-molecule junctions) can be made to act as a variety of circuit elements
including resistors, switches, transistors, and, indeed, diodes. They have learned that it is possible to see quantum mechanical effects, such as interference, manifest in the conductance properties of molecular junctions.
Since a diode acts as an electricity valve, its structure needs to be asymmetric so that electricity flowing in one direction experiences a different environment than electricity flowing in the other direction.
In order to develop a single-molecule diode, researchers have designed simply molecules that have asymmetric structures.""While such asymmetric molecules do indeed display some diode-like properties,
they are not effective, "explains Brian Capozzi, a Phd student working with Venkataraman and lead author of the paper."
"A well-designed diode should only allow current to flow in one direction--the'on'direction
--and it should allow a lot of current to flow in that direction. Asymmetric molecular designs have suffered typically from very low current flow in both'on and off'directions,
and used gold metal electrodes of different sizes to contact the molecule. Their results achieved rectification ratios as high as 250: 50 times higher than earlier designs.
including those that are made with graphene electrodes.""It's amazing to be able to design a molecular circuit,
where the light enters through a transparent negative electrode, in our case made of zinc oxide,
and help apply DNA technology to the fabrication of nanoscale semiconductor and plasmonic structures. Sponsored by the National Science Foundation and NASA,
Columbia Engineering researchers first to create a single-molecule diode--the ultimate in miniaturization for electronic devices--with potential for real-world applications May 25th,
enabling us to fit more electronics in a smaller space.""A 3d structure enables storage of significantly more power in less space than is possible with conventional batteries,
"Three-dimensional, porous materials have been regarded as an obstacle to building electrodes. But we have proven that this is not a problem.
While flexible and stretchable electronics already exist, the insensitivity to shock and impact are somewhat new."
and his work on aerogels is in the basis for the invention of soft electronics. Another partner is leading battery researcher, Professor Yi Cui from Stanford university t
are an important component used by the electronics, communications and automobile industries, as well as in radars and other applications.
Superconductors are regarded as one of the most promising candidates for next-generation advanced electronic devices, because the unique quantum effects in superconductors are a great advantage in achieving the energy saving
-273°C)* 1. It has also been a big challenge to realize the high-density integration of superconductors into electronic devices.
The ultrathin high-Tc superconductor would effectively contribute to the significant downsizing and consequent high-density integration in electric circuits,
leading to the realization of future-generation electronic devices with high energy-saving and ultrahigh-speed operation.
Gallium nitride (Gan) and Indium Gallium nitride (Ingan) Technology Targets Fast-growing Markets for Wearable Vision Systems Abstract:
Leti researchers have developed gallium nitride (Gan) and indium gallium nitride (Ingan) LED TECHNOLOGY for producing high-brightness, emissive microdisplays for these uses,
which are expected to grow dramatically in the next three to five years. For example, the global research firm Marketsandmarkets forecasts the market for head up displays alone to grow from $1. 37 billion in 2012 to $8. 36 billion in 2020. urrently available microdisplays for both head-mounted
and 3d heterogeneous integration of such LED arrays on CMOS active-matrices. These innovations make it possible to produce a brightness of 1 million cd/m for monochrome devices
The electromagnetic radiation discharged by electronic equipment and devices is known to hinder their smooth operation. Conventional materials used today to shield from incoming electromagnetic waves tend to be sheets of metal or composites,
They're widely expected to improve energy storage, sensors, nanoelectronics, catalysis and separations, but graphene aerogels are prohibitively expensive and difficult to produce for large-scale applications because of the complicated purification
the team's new aerogel has the lowest adjunction and widest effective bandwidth--with a reflection loss below-10 decibels.
In terms of applications, based on the combination of low adjunction and a"wide"effective bandwidth, the researchers expect to see their 3-D PPY aerogel used in surface coatings for aircraft.
Further potential applications could also be flexible and stretchable electronic devices, luminescent actuators, batteries, smart cloths or sacrificial templates for the growth of new materials.
Molecular machines, novel sensors, bionic materials, quantum computers, advanced therapies and much more can emerge from this endeavour.
Gallium nitride (Gan) and Indium Gallium nitride (Ingan) Technology Targets Fast-growing Markets for Wearable Vision Systems June 2nd, 2015a major advance in mastering the extraordinary properties of an emerging semiconductor:
Such hot carriers propagate over long distances resulting in novel thermoelectric and optoelectronic phenomena. Researchers of the ICN2 have studied such hot carrier propagation
2015battery Technology/Capacitors/Generators/Piezoelectrics/Thermoelectrics/Energy storage Researchers synthesize magnetic nanoparticles that could offer alternative to Rare earth magnets June 1st,
2015photonics/Optics/Lasers A major advance in mastering the extraordinary properties of an emerging semiconductor: Black phosphorus reveals its secrets thanks to a scientific breakthrough made by a team from Universite de Montreal, Polytechnique Montreal and CNRS in France June 2nd, 2015new heterogeneous wavelength tunable laser diode for high-frequency efficiency June 2nd,
by literally videoing these processes on the nanoscale level using an electron microscope.''The development employed a recently developed process called Liquid Cell Transmission Electron microscopy.
News and information New composite material as CO2 sensor June 8th, 2015industrial Nanotech, Inc. Provides Update June 8th, 2015leti launches new Silicon Impulsetm FD-SOI Development Program,
2015discoveries Researchers analyze the structure of bird feathers to create hues without dye June 8th, 2015new composite material as CO2 sensor June 8th, 2015diffusion and Remote Detection of Hot-Carriers in Graphene June 8th,
2015tissue Engineering Scaffolds Produced from Natural Silk in Iran June 8th, 2015announcements New composite material as CO2 sensor June 8th, 2015industrial Nanotech,
June 8th, 2015new composite material as CO2 sensor June 8th, 2015diffusion and Remote Detection of Hot-Carriers in Graphene June 8th,
2015a major advance in mastering the extraordinary properties of an emerging semiconductor: Black phosphorus reveals its secrets thanks to a scientific breakthrough made by a team from Universite de Montreal, Polytechnique Montreal and CNRS in France June 2nd, 2015new heterogeneous wavelength tunable laser diode for high-frequency
Group Hosts Its First MEMS/Sensors Conference Session at Transducers 2015: MIG Speakers Will Explore Technology Transfer, Emerging MEMS/Sensors, Manufacturing Infrastructure and Process Technology, June 23 in Anchorage June 3rd,
2015janusz Bryzek Joins MEMS Industry Group to Lead New TSENSORS Division-New Division will Focus on Accelerating Development of Emerging Ultra-high Volume Sensors Supporting Abundance
, mhealth and Iot May 14th, 2015phonons, arise! Small electric voltage alters conductivity in key materials April 22nd,
Gallium nitride (Gan) and Indium Gallium nitride (Ingan) Technology Targets Fast-growing Markets for Wearable Vision Systems June 2nd, 2015chemists discover key reaction mechanism behind the highly touted sodium-oxygen battery May 28th,
and compact electronics, can be created with simple equipment and common materials. Skyrmions, discovered just a few years ago,
Transistors, which form the basis of today's computing, are tiny devices that stop the flow of electric current (off and on,
Graphene and diamonds prove a slippery combination June 10th, 2015chip Technology Iranian Researchers Model, Design Optical Switches June 13th, 2015new boron compounds for organic light-emitting diodes:
Luminescent blue boron-containing nanographenes are highly promising materials for portable electronic devices June 10th, 2015rice researchers make ultrasensitive conductivity measurements:
ultrasensitive magnetoplasmonic sensors June 11th, 2015lehigh University researchers unveil engineering innovations at Techconnect 2015: Techconnect is the world's largest accelerator for industry-vetted emerging-technologies ready for commercialization June 11th, 2015synthesis of Special Nanoparticles in Iran to Increase MRI Contrast June 11th, 2015investigation of Optical
"Ionics, ion-based data processing and energy conversion, is the electronics of the future, "says Jennifer Rupp, a professor of Electrochemical Materials at ETH Zurich,
for example, in lambda sensors of automotive catalytic converters and solid oxide fuel cells. The ETH professor is convinced that the industrial importance of these materials will even further increase-for example, in gas sensors, new classes of data storage and computer circuits,
and in the conversion of chemical energy into electrical energy and vice versa. One of the most important research questions in Rupp's field currently is how to optimise these materials,
Electrode design affects buckling profilethe researchers also found that the arrangement of the electrodes affects the buckling profile of the ceramic membrane
This supports the development of future gas sensors, ion-based data storage and micro energy converters, such as fuel cells-and potentially a range of other as yet unknown applications in the promising field of ionics.##
Literature reference News and information Designer electronics out of the printer: Optimized printing process enables custom organic electronics June 16th, 2015pixelligent Closes $3. 4 Million in Funding:
Capital Will be used to Support Partner & Customer Product Introductions and Increase Manufacturing Capacity June 16th, 2015renishaw's invia confocal Raman microscope system is being used in conservation activities at the Rijksmuseum in Amsterdam, The netherlands June 16th, 2015solar cells in the roof and nanotechnology in the walls June 16th, 2015chip Technology
Graphene and diamonds prove a slippery combination June 10th, 2015sensors Designer electronics out of the printer:
Optimized printing process enables custom organic electronics June 16th, 2015binghamton engineer creates origami battery June 10th, 2015mipt physicists develop ultrasensitive nanomechanical biosensor June 9th, 2015new composite material as CO2 sensor June 8th, 2015discoveries Designer electronics out of the printer:
Optimized printing process enables custom organic electronics June 16th, 2015nanoparticles naturally fall into left-and right-handed versions June 16th,
2015researchers create transparent, stretchable conductors using nano-accordion structure June 16th, 2015researchers grind nanotubes to get nanoribbons:
Rice-led experiments demonstrate solid-state carbon nanotube'templates'June 15th, 2015materials/Metamaterials Designer electronics out of the printer:
Optimized printing process enables custom organic electronics June 16th, 2015pixelligent Closes $3. 4 Million in Funding: Capital Will be used to Support Partner & Customer Product Introductions and Increase Manufacturing Capacity June 16th, 2015solar cells in the roof and nanotechnology in the walls June 16th, 2015global Nanoclays Market Analysis
electronics out of the printer: Optimized printing process enables custom organic electronics June 16th, 2015nanoparticles naturally fall into left-and right-handed versions June 16th,
2015researchers create transparent, stretchable conductors using nano-accordion structure June 16th, 2015world's thinnest lightbulb--graphene gets bright!
Columbia engineers and colleagues create bright, visible light emission from one-atom thick carbon June 15th, 2015energy Designer electronics out of the printer:
Optimized printing process enables custom organic electronics June 16th, 2015solar cells in the roof and nanotechnology in the walls June 16th, 2015industrial Nanotech,
2015battery Technology/Capacitors/Generators/Piezoelectrics/Thermoelectrics/Energy storage Binghamton engineer creates origami battery June 10th, 2015ultrafast heat conduction can manipulate nanoscale magnets June 8th, 2015diffusion and Remote Detection of Hot-Carriers in Graphene June 8th,
#New Sensors Measure Blood Anticoagulation Drug Iranian researchers from Isfahan University of Technology produced a highly sensitive and accurate sensor
The sensor was produced through a simple and cost-effective method and its application does not require advanced skills.
a simple but very sensitive sensor based on fluorescence spectroscopy was presented by using cadmium telluride quantum dots to quickly measure protamine drug.
Taking into account the fact that this sensor presents a simple and quick method for the measurement of protamine,
In addition to its high speed, this sensor minimizes environmental pollution due to the use of very low concentration of quantum dots in the production of the sensor and the lack of the need for toxic and organic solvents.
Researchers believe that the results of the research can be commercialized due to the advantages of the sensor including quick and fast measurement,
who led the theoretical and modeling aspects of the new imaging technique, adds:""we now have sophisticated a understanding of what the images mean".
2015stanford engineers find a simple yet clever way to boost chip speeds: Inside each chip are millions of tiny wires to transport data;
wrapping them in a protective layer of graphene could boost speeds by up to 30 percent June 18th, 2015a new way to image surfaces on the nanoscale:
2015cellulose from wood can be printed in 3-D June 17th, 2015new Sensors Measure Blood Anticoagulation Drug June 17th, 2015discoveries Scientists film shock waves in diamond:
2015stanford engineers find a simple yet clever way to boost chip speeds: Inside each chip are millions of tiny wires to transport data;
wrapping them in a protective layer of graphene could boost speeds by up to 30 percent June 18th, 2015a new way to image surfaces on the nanoscale:
Method could be useful in developing green energy and a better understanding of rust June 18th, 2015new Sensors Measure Blood Anticoagulation Drug June 17th,
2015announcements Stanford engineers find a simple yet clever way to boost chip speeds: Inside each chip are millions of tiny wires to transport data;
wrapping them in a protective layer of graphene could boost speeds by up to 30 percent June 18th, 2015$8. 5m Grant For Developing Nano Printing Technology:
2015stanford engineers find a simple yet clever way to boost chip speeds: Inside each chip are millions of tiny wires to transport data;
wrapping them in a protective layer of graphene could boost speeds by up to 30 percent June 18th, 2015a new way to image surfaces on the nanoscale:
Method could be useful in developing green energy and a better understanding of rust June 18th, 2015new Sensors Measure Blood Anticoagulation Drug June 17th,
2015research partnerships Stanford engineers find a simple yet clever way to boost chip speeds: Inside each chip are millions of tiny wires to transport data;
wrapping them in a protective layer of graphene could boost speeds by up to 30 percent June 18th, 2015$8. 5m Grant For Developing Nano Printing Technology:
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