The OSU study (CD toxinroduced actin oligomers poison formin-controlled actin polymerization which is published in Science,
a monomer, or a single molecule, and a filament, which is a strand of those molecules strung together.
or a bit of saliva on a small plastic film that has a piece of cellulose plastic on it.
all packed within a flexible, polymer-coated pouch. And unlike lithium-ion batteries which can short circuit
Furthermore, the researchers point out that aluminum is a cheaper metal than lithium, and the aluminum-ion technology offers an environmentally friendly alternative to disposable AA
That alloy is a shape-memory material this means that although it will stay in a shape that it's been bent into
but even in the 1950s, the speed that tapes had to run was more than the plastic could handle without stretching or tearing,
and magnetic readers were developed so the tapes could run back and forth quickly without putting too much strain on the plastic.
The new tape is the result of 13 years of work on a high-density barium ferrite tape combined with new control technology for read write-heads heads involving advanced servo control technologies
where c is the speed of light in vacuum and n denotes the refractive index of the medium in which the light pulse propagates.
The amplitude depends on distance, size, reflectivity and angle of the object with respect to the sensor. An object will be detected by the sensor
"The Veg-01 experiment sees plants grown in zero gravity in a plastic greenhouse that consists of a collapsible plastic tent with a controllable atmosphere that is lit by red, blue,
Polymers like hydrogels carry large amounts of water within their structure which gives them the capacity to respond to variations in environmental factors such as acidity,
the team created an L-shaped polymer and changed the temperature repeatedly to observe its response.
The nanosheets were fixed then in place using a process called light-triggered in-situ vinyl polymerization where the light helped to stick them together within the polymer.
The nanosheets create electrostatic resistance in one direction, but not the other. The polymer"legs"not only lengthened
and contracted at pace, allowing it to move forward, but its overall volume also remained the same.
The L-shaped polymer can walk indefinitely, Ishida says, as long as the heating and cooling cycle is repeated.
#Snake skin-inspired steel could lead to better hard drives and more When it comes to human phobias,
With a fiber laser, they milled scales into a steel bolt of 8 mm in diameter.
With that in mind, researchers at KIT milled scales into a steel bolt 8 mm in diameter using a fiber laser.
Both designs were tested on lubricated (steel) and unlubricated (sapphire) contacts. For lubricated conditions, the untextured surface generated the least amount of friction
even with hard materials like steel and sapphire, it shows that scale-like texturing has potential application for dry-contact devices and/or environments that benefit from low friction and high wear resistance c
The meshes are made from a flexible polymer called POMAC (which is short for this mouthful:"
and bend the polymer meshes.""And when we apply electrical field stimulation, we see that they beat in synchrony."
the engineers used coils of copper wires insulated with PVC tubing. At one end of this arrangement, the wires terminate at a receiver and analyzer,
and Johns hopkins university collaborated on a ground-breaking procedure to produce a 3d printed silicone support structure that is implanted into living tissue to guide
which then produced the silicone nerve guide. The sciatic nerve in the rat was severed then, and the guide was implanted surgically into the rat by grafting it to the sliced ends of the nerve.
The short video below shows the 3d printing process used for the production of the silicone guides u
and the limited visibility that comes with being wrapped in a mobile fortress of ceramic and steel.
#Biodegradable implant could simplify bone replacement surgery Combining cornstarch with volcanic ash clay to create a plastic for bone grafts could make the surgical process of bone replacement much simpler in the future.
or hard plastic in the area may make future procedures easier.""The biodegradable polymer is reinforced with montmorillonite clay nanoparticles (we've seen nanoparticles used in other ways to heal bones) for strength,
and injected with carbon dioxide making the implant look like a kind of rigid foam that is porous like real bone.
"says Mauricio Terrones, professor of physics, chemistry and materials science at Penn State.""We were previously able to dope graphene with atoms of nitrogen,
#Teenage Girl Turns Plastic Trash Into Million-Dollar Biofuel An Egyptian teenager has discovered an inexpensive way to turn plastic trash into fuel
what some scientists are calling iofuelbecause the organic chemicals from plastic polymers she extracts, are the same chemicals extracted from vegetation to create ethanol biofuel.
The little black bundles, framed by stainless steel, were promised to anyone who donated#50 or more.
low-frequency ultrasound can travel through the body without any scattering. Light-based techniques are great for some uses and
the researchers used a custom-built 3d printer to make silicone guides for nerve regeneration. These 3d printed nerve pathways were embedded with biochemical cues to promote growth.
He says ther metals have lower efficiency but higher thrust. So you would need more fuel to get to Mars,
but Neumann has achieved promising results with titanium, aluminium and other widely used metals. Spaceships using his drive might find capturing fuel made from a dead satellite a handy way to refuel,
Neumann says experiments with pulsed electric arcs on metals go back to the 1920s, and some of the data collected was useful to him in assessing
plastic-based material. What about organic materials, such as human organs? Wouldn it be great if new organs could be printed out and used in surgical operations to save people lives?(
These soft materials were not mere plastic copies of biological material: collagens, muscle fibers, miniature brain structures,
a Ph d. candidate in materials science and engineering at the University of Illinois. here no way of doing that today.
and copper supported by silicone. Most of the sensor bulk comes from a 40-micrometer-thick layer of silicone.
Each of the other layers has a thickness of just tens or hundreds of nanometers.
They were built out of small plastic cubes with motors inside. The experiments found that those baby robots passed down all of their best traits.
Apple will use a more reinforced metal for the phone body the reports have indicated. That slightly larger body will have a smaller battery than the iphone 6, according to previous leaks.
N y. For nearly three decades Krishan Luthra stubbornly labored away in a General electric research lab on a long-shot effort to cook up a new type of ceramic that few consumers will ever see or use.
The material is a type of ceramic that is hard and can handle high heat, like the ceramics people have been making for 25,000 years.
But this ceramic is a complex composite that is also very light, and tough like a metal.
No one wants the aircraft engine that is holding them 35,000 feet above the earth to shatter like a vase.
Success came only at the end of a tortured path of fluctuating research funding and disappointments that at times shook Luthra hopes. here were times where
because the alloys would melt. Already, today engines employ elaborate cooling mechanisms that divert air for cooling that otherwise would be used to power the plane.
Ceramic matrix composites can withstand temperatures 20 percent higher than these metals, and they are one-third the weight. or
says Gregory Morscher, a ceramic composites expert and mechanical engineering professor at the University of Akron.
The theoretical qualities of these ceramic composites have long been well known, but Luthra wanted to make them a reality,
and structure of the matrix thin filaments coated with a ceramic that is shaped into a lattice.
One leap forward was a new type of fiber developed in Japan made of silicon carbide.
But coating these fibers with a ceramic each just one eighth the width of a human hair, evenly, was extremely difficult. f you don do that right you get a ceramic that behaves like china,
and if you do it right you get ceramic with metal properties, and that the big deal, he says.
He figured how to apply the coatings to each individual fiber in something called a chemical vapor deposition reactor,
The fibers are bathed then in a polymer that arranges them into a latticelike structure. Then
like all ceramics, the material is baked. The polymer burns away and leaves behind a strong,
light lattice that is later filled with liquid silicon to create a solid structure. GE designed the material into an engine called the LEAP to be used on the coming Airbus 320neo and Boeing 737 MAX.
who manages the LEAP program for GE Aviation division, of the composite. GE says that by 2020,
He wants to improve the composites so they can handle even higher temperatures, and he wants to convince more divisions at GE to use the materials. don want to stop,
director of Berkeley Lab Materials sciences Division. ur ultra-thin cloak now looks like a coat. It is easy to design and implement,
The researchers, from the Electronics and Telecommunications Research Institute and Konkuk Univ. in the Republic of korea, coated cotton and polyester yarn with a nanoglue called bovine serum albumin (BSA.
or tiny crystals that have luminescent properties. Quantum dots (QDS) can be made with numerous materials, some
The device, called Netra, is a plastic, binocular-like headset. Users attach a smartphone, with the startup app, to the front and peer through the headset at the phone display.
In new research, published in the Royal Society of Chemistry's Journal of Materials Chemistry A, they found that some metal-organic frameworks,
as porphyrin is related to chlorophylls, the green pigments which allow plants to convert sunlight into chemical energy,
#Researchers Use Potatoes to Make Eco-friendly Plastic films Using potato peels and culls considered waste by Alberta potato-processing industry,
With applications for both the food packaging and cosmetic industries, the new bioactive film is a green alternative to traditional petroleum-based plastics
Subcritical fluid technology uses water above its boiling point and below its critical temperature, under pressure. In subcritical water medium, starch can be modified to influence the film properties, such as its tensile strength
elongation, and antioxidant and antimicrobial activity. Saldaña team has obtained already an international Patent Cooperation Treaty application for the processing method
or repelled by, a metal surface by changing the polarity of the voltage applied to the metal.
in turn, allows control over the rate of heat transfer between the metal and the liquid.
Peter Nilsson, a chemical biologist at Linköping University in Sweden, was experimenting with conductive plastics,
than regular, crystalline solids. But the new type of glass created by researchers at the University of Chicago
Like a crystal, it has a well-defined molecular organization, de Pablo said in a statement.
including a small polymer panel that literally goes"poof,"changing from a solid into a gas.
The team demonstrated their tractor beam using tiny balls of polystyrene the same material used in packing peanuts.
"The team currently levitates lightweight polystyrene balls that measure up to 0. 2 inches (5 millimeters) across.
The nanoparticles are made of biodegradable polymers called poly (ß-amino esters)( PBAES) and in lab tests were able to pass through mucus taken from real patients.
The Velox valve works with different size mitral annuli and consists of the standard pericardial leaflets on top of a polymer coated nitinol self-expanding structure.
#This company grows super-metals like trees A Seattle start-up called Modumetal could soon do for metal
what 3-D printing has done for plastics, reports Fortune. The company has developed a revolutionary process for"growing"metal that can be likened to how trees grow, according to CEO and cofounder Christina Lomasney.
The method is the ideal way of making materials, she explained. It's similar to the way that other Nature has evolved growing things over eons."
"The key to the method and what makes it so innovative is the use of nanotechnology to micromanage at the tiniest of scales the construction of their metal alloys, layer by layer.
"plywood-like metals with custom-made properties that are superior to conventional materials due to their nano-level detail.
Corrosion resistance isn't the only super-trait of these metals. They can also be made stronger and lighter than steel,
and resistant to temperature changes too. For example, the Defense department has approached the company with interest in the development of new armor that is both bulletproof and light enough to wear.
and using metals like smelting, the Modumetal method requires only electricity. The company hopes its technique will usher in a new era
Ballantine's added a Rose gold mouthpiece to retain what it describes as"that evocative, cold touch on your lip as you drink."
#New ultra-strong, lightweight aluminum-steel alloy invented that rivals titanium Old-fashioned steel has been one of the most reliable and ubiquitous building materials for centuries,
so it might seem a bit outmoded to talk of a steel breakthrough. But researchers at Pohang University of Science and Technology in South korea may have made steel cool again, not to mention stronger and lighter, reports Popular Mechanics.
The researchers have devised a method for creating an aluminum-steel alloy that is more flexible, lightweight and stronger than any kind of steel ever made before.
This isn't the first time anyone has thought to add aluminum to the steel mix. Back in the 1970's
Soviet scientists recognized that by blending steel and aluminum they could forge an ultra-strong, lightweight metal,
but these advantages were always superseded by one major drawback: it was incredibly brittle. When significant force was applied,
it always broke rather than bent. The problem was that when you fuse aluminum and iron atoms together,
it tends to create tough, crystalline structures called B2, which are what make the aluminum-steel alloys so brittle.
No one had ever found a way around this problem, until now. Hansoo Kim and his team at Pohang discovered that
if the B2 crystals could be dispersed properly throughout the steel, the surrounding alloy could insulate them from splintering."
"My original idea was that if I could somehow induce the formation of these B2 crystals,
I might be able to disperse them in the steel, "explained Kim. It's not as simple as it sounds.
Kim and his team spent years painstakingly heat-treating and thinly rolling their steel in repeated attempts to control
when and where B2 crystals were formed. They experimented by adding bits to the mix; nickel, it turns out,
offered the particularly important advantage of making the crystals form at a much higher temperature, for instance.
Finally, they mastered their technique. The result of all this work is a viable aluminum-steel alloy that is 13 percent less dense compared to normal steel,
and with a comparable strength-to-weight ratio compared to titanium alloys. That's significant,
and it could make aluminum-steel alloy the building material of the future.""Because of its lightness, our steel may find many applications in automotive
and aircraft manufacturing,"said Kim m
#How to save soldiers'lives with fizz One of the biggest challenges for medics on the battlefield is treating blood loss,
which is among the leading causes of death for wounded soldiers. Bandages infused with chemicals designed to assist blood clotting helps,
and the University of North carolina at Chapel hill have designed a novel drug release technology that relies on a stretchable elastomer
The patches consist of an elastomer that has tiny capsules throughout its surface each filled with drug loaded nanoparticles.
This pressure comes from stretching of the elastomer film, which in turn stretches the capsules and compresses them to release the drugs.
But in gas sensing applications, copper oxide was much less widely investigated compared to other metal oxide materials.
But in gas sensing applications, copper oxide was much less widely investigated compared to other metal oxide materials.
and electrically active crystals in one direction unlocks exotic spintronic switching activityby breaking the symmetry of ultiferroiccrystals using a special compression cell,
where polarization effects are initiated at ultralow temperatures by changing the crystal internal symmetry. This effect,
By applying pressure to the crystal in a direction that corresponds to a specific crystallographic axis,
The team constructed a unique cell that clamps a multiferroic barium cobalt germanium oxide (Ba2coge2o7) crystal between a pair of zirconium oxide pistons (Fig. 1). They then investigated how the sample electric polarization changed under uniaxial stress.
In contrast, by deforming the Ba2coge2o7 crystal with varying levels of uniaxial stress, the researchers could tune the polarization output in unprecedented ways, from fully on to fully off,
particularly for crystals with high levels of symmetry. any multiferroic materials have the potential to show stress-induced effects,
Lithium metal, for example, can store about 10 times as much energy per gram, but is extremely dangerous,
who has a joint appointment in MIT Department of Materials science and engineering. e came up with the method serendipitously,
Key to the process is the strong Van der waals interaction that exists between graphene and hexagonal boron nitride, another 2d material within
Thanks to strong Van der waals interactions between graphene and boron nitride, CVD graphene can be separated from the copper
Raman spectroscopy and transport measurements on the graphene/boron nitride heterostructures reveals high electron mobilities comparable with those observed in similar assemblies based on exfoliated graphene.
In a paper published August 10, 2015 in the journal Nature Communications, Michael Arnold, an associate professor of materials science and engineering at UW-Madison, Phd student Robert Jacobberger,
when it explored dramatically slowing the growth rate of the graphene crystals by decreasing the amount of methane in the chemical vapor deposition chamber.
the graphene crystals naturally grow into long nanoribbons on a specific crystal facet of germanium. By simply controlling the growth rate and growth time,
It is stronger than steel yet many times lighter more conductive than copper and more flexible than rubber.
and mechanical properties of MOFS compared to materials such as ceramics or metals, and have resulted in the past in structural collapse during postprocessing techniques such as sintering
Dr Thomas Bennett from the Department of Materials science and Metallurgy at the University of Cambridge says:
raditional methods used in melt-casting of metals or sintering of ceramics cause the structural collapse of MOFS due to the structures thermally degrading at low temperatures.
Through exploring the interface between melting, recrystallisation and thermal decomposition, we now should be able to manufacture a variety of shapes
The formation of glasses that contain highly interchangeable metal and organic components, in is highly unusual,
as they are normally either purely organic, for example in solar cell conducting polymers, or entirely inorganic, such as oxide or metallic glasses.
whereby different metals or organics are swapped into, or out of, the MOFS before melting o
director of Berkeley Lab Materials sciences Division and a world authority on metamaterials artificial nanostructures engineered with electromagnetic properties not found in nature. ur ultra-thin cloak now looks like a coat.
It is the scattering of light be infrared it visible , X-ray, etc.,from its interaction with matter that enables us to detect
Adsorption of molecules from solution onto a sensing surface alters the refractive index of the medium near this surface and,
or polymer layers on it. The biosensing sensitivity depends on the properties of chip surface. Higher binding capacity for biomolecules increases the signal levels and accuracy of analysis. The last several years
the chemical process in this case controls magnetism in carefully chosen strongly ferromagnetic material systems. The working principle used in this case is similar to the concept of lithium-ion batteries.
"UW researchers used chemical vapor deposition to grow graphene nanoribbons on germanium crystals. This technique flows a mixture of methane, hydrogen,
armchair edges,"said Michael Arnold, an associate professor of materials science and engineering at UW-Madison.""The widths can be very, very narrow,
"Not only are designed our facilities to work with all different sorts of materials from metals to oxides,
"What's even more interesting is that these nanoribbons can be made to grow in certain directions on one side of the germanium crystal,
each face of a crystal (1, 1, 1) will have axes that differ from one (1, 1, 0) to the other (1, 0,
A tiny flake of graphene on silicon carbide and a futuristic-looking antenna and there it is the new graphene detector.
Wide spectral range achieved through silicon carbide substratethe choice of substrate has now proved a pivotal step in improving the little light trap."
but silicon carbide remains passive in the spectral range, "explained Stephan Winnerl. Then there is also an antenna which acts like a funnel and captures long-wave infrared and terahertz radiation.
which is located in the center of the structure on a silicon carbide substrate t
#Graphene flakes as an ultra-fast stopwatch Scientists at the Helmholtz-Zentrum Dresden-Rossendorf (HZDR), working with colleagues from the USA and Germany, have developed a new optical detector from graphene
A tiny flake of graphene on silicon carbide and a futuristic-looking antenna and there it is the new graphene detector.
Wide spectral range achieved through silicon carbide substrate The choice of substrate has now proved a pivotal step in improving the little light trap."
but silicon carbide remains passive in the spectral range, "explained Stephan Winnerl. Then there is also an antenna which acts like a funnel and captures long-wave infrared and terahertz radiation.
At that point, a reflective metal layer is on the bottom.""In this structure-unlike other photodetectors-light absorption in an ultrathin silicon layer can be much more efficient
At that point, a reflective metal layer is on the bottom.""In this structure-unlike other photodetectors-light absorption in an ultrathin silicon layer can be much more efficient
Other authors are graduate student Ritchie Chen and Polina Anikeeva, an assistant professor of materials science and engineering. Magnetic pull Previous research has yielded synthetic magnetic particles for imaging
The technique was demonstrated with polystyrene particles i
#An important step in artificial intelligence: Researchers in UCSB's Department of Electrical and Computer engineering are seeking to make computer brains smarter by making them more like our own Abstract:
Measurement of a single nuclear spin in biological samples May 11th, 2015graphene holds key to unlocking creation of wearable electronic devices May 11th, 2015new Method to Produce Dual Zinc oxide Nanorings May 11th
Measurement of a single nuclear spin in biological samples May 11th, 2015graphene holds key to unlocking creation of wearable electronic devices May 11th, 2015new Method to Produce Dual Zinc oxide Nanorings May 11th
Measurement of a single nuclear spin in biological samples May 11th, 2015graphene holds key to unlocking creation of wearable electronic devices May 11th, 2015new Method to Produce Dual Zinc oxide Nanorings May 11th
Measurement of a single nuclear spin in biological samples May 11th, 2015graphene holds key to unlocking creation of wearable electronic devices May 11th, 2015new Method to Produce Dual Zinc oxide Nanorings May 11th
a moth's eyes are antireflective because of naturally covered tapered nanostructures where the refractive index gradually increases as light travels to the moth's cornea,
"This produces a surface consisting of a porous three-dimensional network of high-silica content glass that resembles microscopic coral."
A portion of the research was conducted at the Center for Nanophase Materials sciences, a DOE Office of Science User Facility.
Electrodes that so far have been used are made of very expensive elements such as platinum or platinum-iridium alloys.
This new composite presents some special talents. Firstly, it produces under sun light illumination a photovoltage of almost 0. 5 volts and very high photocurrent densities of up to 38 ma/cm2;
in order to optimize the properties of the novel composite photoelectrode device. The properties were optimal with a volumetric proportion of about 5%platinum (H2ptcl6) in the precursor solution."
In addition, it has been reported in the very recently published article that the composite shows high long-term stability over 25 hours
For example, after the implantation of an artificial ureter, urease crystals often start to grow inside
or into flexible chains through soft molecular linkers such as surface-grafted DNA or polymers. Here, we show that capillarity-mediated binding between magnetic nanoparticles coated with a liquid lipid shell can be used for the assembly of ultraflexible microfilaments and network structures.
it becomes pure tantalum, a metal. The researchers determined three related factors give the memories their unique switching ability.
Tour is the T. T. and W. F. Chao Chair in Chemistry as well as a professor of materials science and nanoengineering and of computer science and a member of Rice's Richard E. Smalley Institute for Nanoscale Science and Technology y
and nanostructures to naturally occurring biological polymers, tissues and plant cells. The first application as part of DOE's Bioenergy Science Center was in the examination of plant cell walls under several treatments to provide submicron characterization.
They have managed also to use the polymer to build an L-shaped object that slowly walks forward as the temperature is raised repeatedly and lowered.
Hydrogels are polymers that can maintain large quantities of water within their networks. Because of this, they can swell
and then fixed them in place using a procedure called light-triggered in-situ vinyl polymerization, which essentially uses light to congeal a substance into a hydrogel.
The nanosheets ended up stuck within the polymer, aligned in a single plane. Due to electrostatic forces, the sheets create electrostatic resistance in one direction but not in the other.
which we calculated to be 32 degrees Celsius, the polymer rapidly changed shape, stretching in length.
As a demonstration of how the polymer could be put to practical use, the group designed an L-shaped piece of polymer that can actually walk, in a water environment,
as the legs lengthen and contract in response to changing temperature. The group now plans to conduct further studies to create substances that can be used in practical applications.
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