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Recent Warfare Technologies

This is a very exotic application (although solar sails could be used in Earth orbit to make satellites perform tasks that they could not do in passive orbits), but the line that stood out in my mind was
Multiwall carbon nanotube sheets have been made with a mass of ~27 milligrams per square metre and about the strength of kevlar

Super strong and ultra light material has so many applications it isn't funny. Reducing the weight of things like body armour, packs, tentage and so on to a few grams would have fantastic follow on effects both tactically and throughout the logistics train. This material is also similar to fiberglass, if processed as described in the article it may replace structural material in multiple applications as well.

http://nextbigfuture.com/2013/02/carbon-nanotube-sheets-for-solar-sails.html

Carbon nanotube sheets for solar sails for 5.6% of lightspeed

Multiwall carbon nanotube sheets have been made with a mass of ~27 milligrams per square metre and about the strength of kevlar. Adam Crowl of Crowlspace examines this a bit more. Nextbigfuture covered the dry spinning of carbon nanotubes into sheets back in 2007.

The self-supporting MWNT sheets initially form as a highly anisotropic aerogel that can be densfied into strong sheets that are as thin as 50 nm. The areal density of the sheet is 30 mg/m and there is no fundamental limit on sheet width or length. The measured gravimetric strength of orthogonally oriented sheet arrays exceeds that of the highest strength steel sheet.

In theory that means a suitably steered solar-sail made of CNT sheet could send itself away from Earth’s orbit and reach a final speed of 42*sqrt(57-1) km/s ~ 315 km/s. If it swooped past Jupiter then swung in hard for the Sun, scooting past at 0.019 AU, then it would recede at ~2,200 km/s (0.73 % of lightspeed).

A spaced out grid of carbon nanotubes with doping to have 100% reflectivity could achieve 5.6% of lightspeed.

Atomic layer deposition for solar sails almost as good as carbon nanotubes

Beneq has successfully scaled up its proprietary continuous ALD (atomic layer deposition) process to a 500 mm (half of meter. 20 inches) wide web using the R2R (roll to roll) manufacturing method.

The material developed for the proposed Drexler solar sail was a thin aluminum film with a baseline thickness of 0.1 micrometres (100 nanometers), to be fabricated by vapor deposition in a space-based system. Drexler used a similar process to prepare films on the ground. As anticipated, these films demonstrated adequate strength and robustness for handling in the laboratory and for use in space, but not for folding, launch, and deployment. Vapor deposition aluminum at 100 nanometer thickness would mass less than 0.1 grams/meter.

A lot of small solar sails could also form a matter beam that would hit the pusher plate of a larger and heavier spacecraft. This would allow a large and heavy spacecraft to achieve the speeds that the solar sails could reach.

Ikaros

Japan's JAXA successfully tested IKAROS in 2010. The goal was to deploy and control the sail and for the first time determining the minute orbit perturbations caused by light pressure. Orbit determination was done by the nearby AKATSUKI probe from which IKAROS detached after both had been brought into a transfer orbit to Venus. The total effect over the six month' flight was 100 m/s.

IKAROS has a diagonal spinning square sail 20 m (66 ft) made of a 7.5-micrometre (0.0075 mm) thick sheet of polyimide. A thin-film solar array is embedded in the sail. Eight LCD panels are embedded in the sail, whose reflectance can be adjusted for attitude control. IKAROS spent six months traveling to Venus, and then began a three-year journey to the far side of the Sun
 
A different way of looking at exoskeleton technology:

http://nextbigfuture.com/2013/02/light-weight-and-low-power-exoskeletons.html#more

Light Weight and Low Power Exoskeletons for Injury Prevention are US Army Focus

Developing an expensive and energy-hungry super suit, though a nice idea, might not be the military’s top priority. Augmenting soldiers’ natural strength and protecting them from injuries is another matter: Darpa is now working on a new programme called Warrior Web, which is much closer in inspiration to Batman than Iron Man. Rather than relying on a hard, exterior robotic shell, the Warrior Web suit is described as being a “lightweight, conformal undersuit”, like a diver’s wetsuit.

The undersuit takes a different approach to enhancing soldiers: rather than creating “super soldiers” that can carry much more than a normal human, it focuses on helping troops do what they already do more efficiently and safely: carrying gear and supplies which can reach over 100 pounds (45kg). The idea is that the suit will fit comfortably underneath the uniform and outer protective gear to provide functional and adaptive support. Integrated components and sensors will help to prevent injuries and enhance the user’s natural abilities by supporting joints and reducing the amount of energy a soldier expends. Darpa is also looking at other “novel technologies that prevent, reduce, ambulate, and assist with healing of acute and chronic musculoskeletal injuries.”

2007 DOD statistics about military injuries:

* There were 2.1 million injury-related medical visits, affecting 900,000 service members.
* Injuries were the second cause of hospitalizations, accounting for almost 110,000 days in hospital.
* Injuries were, and are, the leading cause of outpatient clinical visits.
* Musculoskeletal injuries accounted for 68 percent of all limited-duty days and medical profiles; they add up to an estimated 25 million limited-duty days per year.

The injury rate for the Army is 2,500 reported injuries for every 1,000 Soldiers. This means that every Soldier could potentially to go to sick call at least twice a year for a musculoskeletal injury. Injuries that affect the low back, knee, ankle and shoulders account for most of the visits.



The “Warrior Web” suit, according to Darpa, should not require “more than 100 Watts of electric power from the battery source.”Th

The vision of the Warrior Web program is to develop and demonstrate an adaptive, compliant, quasipassive undersuit that will reduce injury and enhance soldier performance. Warrior Web Task A focused on development and demonstration of component technologies at specific musculoskeletal joints, (i.e., muscle augmentation, regenerative kinetics, advanced textiles, sensing and control elements, joint stabilization, biomechanical modeling using OpenSIM, and overall reduced metabolic consumption). Warrior Web Task B seeks the development and demonstration of an integrated suit that incorporates multiple proven component technologies into a conformal, comfortable form factor that is suitable for use by the average soldier. Additionally, Task B performers will be expected to leverage the program’s selected modeling environment, a freely available OpenSIM biomechanical model, in order to perform initial design validation.
 
The ultimate evolution of computing using known technology. This would be like having a server farm in a wrist watch (Google houses computers in warehouses, to give you an idea of scale):

http://nextbigfuture.com/2013/03/dna-3d-nand-gate-bricks-would-be-able.html

DNA 3D Nand Gate Bricks Would Be Able to Make a Computer with 1 million times the transistors of Intel Itanium Poulson Computers

Harvard researchers have used single strand DNA, to self assemble custom designed nano scale structures. Each of the bricks shown to the left is, 25-nanometers on a side, they are composed of ~1,000 voxels (I think it is 500 DNA strand, 2 voxels per strand) unique single strands of DNA, each with 32 nucleotides. Each strand is like a jigsaw puzzle piece and can only bind in one location. This is due to the fact that nucleotides only bind to their opposites, A to T and G to C. These DNA strands can be designed to self assemble into pretty much any shape, as shown in the image.

David Fuchs at Hephastus Project outlines what kind of computing would be possible with 25 nanometer 3D Nand bricks.

A one inch cube could hold 1,000,000,000,000,000,000 of these 25 nm bricks.

Using two simple techniques, you can build much larger structures out of smaller ones. The first technique is to create binding sites, on each of the six sides of the brick. The second technique is to create a spacer-binder with matching but opposite nucleotides to bind to.

NOTE - Limiting factors.
* cost to produce this much DNA is still out of reach
It costs $2 billion to synthesize the billions of base pairs for the human genome. There are some approaches which could lower the cost by 10,000 to 100,000 times but that is still $20,000 for a human genome. Even if short sequence DNA brick synthesis is a lot cheaper in massively parallel production that has to be very cheap synthesis of 260 billion billion 25 nanometer bricks.

* connecting it and making the structure and logic for useful work and providing the skeleton for massive number of bricks seems to pretty much need full blown molecular nanotechnology.

* there is also the heat management issues

The NAND logic gate is the universal gate, with it you can build all other logic gates, NOT, AND, OR, NOR, XOR, and XNOR. By extension, using only NAND gates you can build any logic circuit imaginable, processor, memory, and any other logic circuit you can conceive of or need.

6 Inch cube of DNA 3D Nand Bricks

The concept for the Three Dimensional Configurable NAND Gate is simple. It is a cube with a NAND gate inside. The cube NAND gate has the following specifications.

* A cube NAND gate has six sides, each side can be individually turned on for input, output, or set as unused.
* A used cube NAND gate, must have at least one input and one output.
* When only one input is used, the gate acts as a NOT gate.
* All outputs of a single cube NAND gate output the same signal.
* A cube NAND gate can either be in use and logically connected to other cube NAND gates, or unused and not logically connect to any other NAND gates.

216,000,000,000,000,000,000 individual NAND gates. This does not take into account the spacer binders, the need for cooling, long range (over 1,000 nm) communications, and power. David chose to ignore them because this is a speculative piece. Adding all the missing pieces listed above takes about half the volume and ~halves the number of NAND gates, again we are ignoring that. We just want to see roughly what can be done.

A system consist of

* An Intel 8-Core Itanium Poulson
* 2 Terabytes of RAM
* 1 Terabyte hard drive

Would need about 128 trillion transistors.

A six inch cube of 3D NAND would be able to fit ~1.8 million maxed out Intel 8 core systems.
Roughly halving it for the cooling and communication and power would be about 1 million systems.


The ability to selectively attach or bind to specific nano-scale structures or specific chemicals and move them into position, with atomic precision, will more than likely occur within the next 3 to 6 years. By combining the technology of DNA bricks and selective manipulation of nano-scale objects, devices such as the configurable 3D NAND gate can be constructed. This is just one small step away from full blown nanotechnology (Drexlerian or other).
 
Thucydides said:
(Google houses computers in warehouses, to give you an idea of scale)

Warehouse doesn't quite do it justice. I've seen one in NC which is moderate in size (so I've been told) that is huge, comparable to a major auto factory.

http://www.google.com/about/datacenters/
 
This technology has all kinds of uses. Cooling sensors for very high performance is the obvious one, but with that amount of cooling power (and especially the low energy consumption to get it), versions of this can be used to cool electronics like laptop and tablet computers, or even large enclosed spaces. Cupper's example of a factory sized data center probably has industrial sized air conditioners and HVAC equipment that consumes a good fraction of the power; a small fleet of these coolers (for backup) could do the same job for a tiny fraction of the price and power consumption:

http://www.nist.gov/pml/div686/refrigerator-030513.cfm

NIST Quantum Refrigerator Offers Extreme Cooling and Convenience

From NIST Tech Beat: March 5, 2013

Contact: Laura Ost
303-497-4880

Researchers at the National Institute of Standards and Technology (NIST) have demonstrated a solid-state refrigerator that uses quantum physics in micro- and nanostructures to cool a much larger object to extremely low temperatures.
quantum refrigerator

NIST's prototype solid-state refrigerator uses quantum physics in the square chip mounted on the green circuit board to cool the much larger copper platform (in the middle of the photo) below standard cryogenic temperatures. Other objects can also be attached to the platform for cooling.

What's more, the prototype NIST refrigerator, which measures a few inches in outer dimensions, enables researchers to place any suitable object in the cooling zone and later remove and replace it, similar to an all-purpose kitchen refrigerator. The cooling power is the equivalent of a window-mounted air conditioner cooling a building the size of the Lincoln Memorial in Washington, D.C.

"It's one of the most flabbergasting results I've seen," project leader Joel Ullom says. "We used quantum mechanics in a nanostructure to cool a block of copper. The copper is about a million times heavier than the refrigerating elements. This is a rare example of a nano- or microelectromechanical machine that can manipulate the macroscopic world."

The technology may offer a compact, convenient means of chilling advanced sensors below standard cryogenic temperatures—300 milliKelvin (mK), typically achieved by use of liquid helium—to enhance their performance in quantum information systems, telescope cameras, and searches for mysterious dark matter and dark energy.

As described in Applied Physics Letters,* the NIST refrigerator's cooling elements, consisting of 48 tiny sandwiches of specific materials, chilled a plate of copper, 2.5 centimeters on a side and 3 millimeters thick, from 290 mK to 256 mK. The cooling process took about 18 hours. NIST researchers expect that minor improvements will enable faster and further cooling to about 100 mK.

The cooling elements are sandwiches of a normal metal, a 1-nanometer-thick insulating layer, and a superconducting metal. When a voltage is applied, the hottest electrons "tunnel" from the normal metal through the insulator to the superconductor. The temperature in the normal metal drops dramatically and drains electronic and vibrational energy from the object being cooled.

NIST researchers previously demonstrated this basic cooling method** but are now able to cool larger objects that can be easily attached and removed. Researchers developed a micromachining process to attach the cooling elements to the copper plate, which is designed to be a stage on which other objects can be attached and cooled. Additional advances include better thermal isolation of the stage, which is suspended by strong, cold-tolerant cords.

Cooling to temperatures below 300 mK currently requires complex, large and costly apparatus. NIST researchers want to build simple, compact alternatives to make it easier to cool NIST's advanced sensors. Researchers plan to boost the cooling power of the prototype refrigerator by adding more and higher-efficiency superconducting junctions and building a more rigid support structure.

This work is supported by the National Aeronautics and Space Administration.
* P.J. Lowell, G.C. O'Neil, J.M. Underwood and J.N. Ullom. Macroscale refrigeration by nanoscale electron transport. Applied Physics Letters. 102, 082601 (2013); Published online 26 Feb. 26, 2013. http://dx.doi.org/10.1063/1.4793515.
** See 2005 NIST Tech Beat article, "Chip-scale Refrigerators Cool Bulk Objects," at www.nist.gov/pml/div686/chip_scale_042105.cfm.

Edit to add link
 
cupper said:
Warehouse doesn't quite do it justice. I've seen one in NC which is moderate in size (so I've been told) that is huge, comparable to a major auto factory.

http://www.google.com/about/datacenters/
So I clicked on the link and then selected self guided tour via Google Street View. Once the window opened I scrolled to the left and there was a Storm-Trooper and mini R2D2 standing guard! Classic Google sense of humour..
 
On the topic of robots, MIT has developed a high efficiency "Cheetah" robot. This is different from the Boston Dynamics high speed robot (or the "Big Dog" load carriers). A robotic "partner" which can move at high speed could have all kinds of uses, from perimeter security to delivering urgently needed supplies. Future dismounted sections (or dismounted troops in general) may have a team of robotic assistants to do things like carry loads, provide sensor data or deliver heavy firepower (Imagine a "Big Dog" robot armed with a .50 HMG or 40mm AGL, for example). Other robot partners could unload trucks, carry casualties or otherwise extend the abilities of the human soldiers:

http://web.mit.edu/newsoffice/2013/mit-cheetah-robot-0308.html

MIT ‘cheetah’ robot rivals running animals in efficiency
Robot’s custom-designed electric motors are powerful and efficient.
Jennifer Chu, MIT News Office

A 70-pound “cheetah” robot designed by MIT researchers may soon outpace its animal counterparts in running efficiency: In treadmill tests, the researchers have found that the robot — about the size and weight of an actual cheetah — wastes very little energy as it trots continuously for up to an hour and a half at 5 mph. The key to the robot’s streamlined stride: lightweight electric motors, set into its shoulders, that produce high torque with very little heat wasted.

The motors can be programmed to quickly adjust the robot’s leg stiffness and damping ratio — or cushioning — in response to outside forces such as a push, or a change in terrain. The researchers will present the efficiency results and design principles for their electric motor at the International Conference on Robotics and Automation in May.

Sangbae Kim, the Esther and Harold E. Edgerton Assistant Professor in MIT’s Department of Mechanical Engineering, says achieving energy-efficiency in legged robots has proven extremely difficult. Robots such as Boston Dynamic’s “Big Dog” carry heavy gasoline engines and hydraulic transmissions, while other electrically powered robots require large battery packs, gears, force sensors and springs to coordinate the joints in a robot’s leg. All this weighty machinery can add up to significant wasted energy, particularly when a robot’s legs need to make frequent contact with the ground in order to trot or gallop.

“In order to send a robot to find people or perform emergency tasks, like in the Fukushima disaster, you want it to be autonomous,” Kim says. “If it could run for more than two hours and search a large field, that would be useful. But one of the reasons why people think it’s impossible to make an electric robot that does this is because efficiencies have been pretty bad.”

Kim adds that part of the challenge in powering running machines with electric motors is that such robots require a flexible response upon impact, and high power, torque and efficiency — characteristics that have historically been difficult to achieve with electric motors.


Watch more videos from the Biomimetic Robotics Lab on YouTube.

To understand how an electrically powered system might waste little energy while running, the researchers first looked at general sources of energy loss in running robots. They found that most wasted energy comes from three sources: heat given off by a motor; energy dissipated through mechanical transmission, such as losses to friction through multiple gear trains; and inefficient control, such as energy lost through a heavy-footed step, as opposed to a smoother and more gentle gait.

The group then came up with design principles to minimize such energy waste. To combat heat loss from motors, the group proposed a high-torque-density motor — a motor that produces a significant amount of torque at a given weight and heat production. The team analyzed the relationship between motor size and torque, and designed custom motors that exceed the torque performance of commercially available electric motors.

The team found that such high-torque motors require fewer gears — a characteristic that would improve efficiency even more, as there would be less machinery through which energy could dissipate. Many researchers have used springs and dampers in series with motors to protect the robot from forceful impacts during locomotion, but it’s difficult to control a spring’s stiffness and damping ratio — which can be a problem if a robot has to traverse disparate surfaces, such as asphalt and sand.

“With our system, we can make our robotic leg behave like a spring or damper without having physical springs, dampers or force sensors,” Kim says.

Kim is the Esther and Harold E. Edgerton Assistant Professor in MIT’s Department of Mechanical Engineering. Photo: M. Scott Brauer

In addition to heat given off by a motor, the group found that another major source of energy loss comes from the force of impact as a robot’s leg hits the ground. Such forces can be strong enough to shake a machine and potentially cause damage. Engineers need to use dampers, or shock absorbers, to minimize shaking and stabilize such systems. But Kim says such dampers act to dissipate energy each time a leg meets the ground.

In contrast, the cheetah-bot’s electric motors capture this energy, feeding it back to the system to further power the robot.

“The majority of impact energy goes back to the battery because the damping is created by custom-designed electric control of the motor,” Kim says. “[The motor] regenerates energy that would have been lost.”

Kim adds that mounting motors and gears at the hip joint would also reduce energy loss by minimizing leg inertia: Some legged robots are designed with motors and gearboxes at each joint along a leg, which can be cumbersome and can lose more energy at every impact. With Kim’s design, 85 percent of the weight of the leg is concentrated at the hip joint, keeping the rest of the leg relatively lightweight.

The researchers also attached strips of Kevlar to connect sections of the robot’s legs, simulating the structure of tendons along a bone. The Kevlar strengthens the leg with little additional weight, and further reduces the leg’s inertia. The group also constructed a flexible spine out of rings of polyurethane rubber, sandwiched between vertebra-like segments. Kim hypothesizes that the spine moves along with the rear legs, and can store elastic energy while galloping.

To test the efficiency of the robot, the researchers ran it on a treadmill at a steady 5-mph clip. They measured the voltage and current of the battery, as well as that from each motor. They calculated the robot’s efficiency of locomotion — also known as cost of transport — and found that it was more efficient than robotic competitors such as Big Dog and Honda’s two-legged robot, ASIMO.

After digging through the literature on animal locomotion, the researchers plotted the cost of transport of various running, flying and swimming animals. They found that, not surprisingly, fliers were more efficient than runners, although swimmers were the most efficient movers. The cheetah robot, according to Kim’s calculations, falls around the efficiency range of humans, cheetahs and hunting dogs.

Currently the team is assembling a set of new motors, designed by Jeffrey Lang, a professor of electrical engineering at MIT. Kim expects that once the group outfits the robot with improved motors, the cheetah robot will be able to gallop at speeds of up to 35 mph, with an efficiency that rivals even fliers. The researchers are convinced that this approach can exceed biological muscle in many aspects, including power, torque and responsiveness.

“There are so many ways to design, and each legged robot has a different system,” Kim says. “If you design the motor properly, it’s more powerful, simpler robotics.”

Ron Fearing, a professor of electrical engineering and computer science at the University of California at Berkeley, says that simple springs can work well in small robots running on smooth terrain. But for rougher, more unpredictable terrain, he says the energy-recovery system of the MIT cheetah has big advantages.

“The cheetah robot has really pushed the technology in efficient motor design, low-loss transmissions, and low-inertia legs,” says Fearing, who did not contribute to the research. “By combining these with the regenerative motor drive system, so that mechanical energy from the leg can recharge the battery, that in my opinion has made a huge difference in efficiency, [and] an important step forward in making efficient, electrically driven running robots.”

In addition to Kim and Lang, the paper’s co-authors include Sangok Seok, Albert Wang, Meng Yee Chuah and David Otten, all of MIT.

This research was funded by the Defense Advanced Research Projects Agency’s Maximum Mobility and Manipulation (M3) program.

Many of the technologies used in this robot, such as high efficiency motors, drive trains and high strength parts can also be transitioned to other applications as well.
 
Long article, but very interesting look at how Google manages giant server clusters. There are obvious advantages to doing so even with smaller data centers like the CF uses, or even using this sort of software to tie lan segments together to create "virtual" datacenters using the power of all the computers in the office. (Consider that the vast majority of the processor power and even hard drive space on your desktop PC is going unused while you write a memo, read your email or build PowerPoint slide shows. Now multiply that by the number of computers in your office building or armoury...)

http://www.wired.com/wiredenterprise/2013/03/google-borg-twitter-mesos/all/

 
Given the growing popularity and uses of UAVs and UCAVs, being able to extend their range by intelligent use of thermals, wind currents and other performance enhancements that glider pilots (and birds) use will be an interesting way to get more performance at little additional cost (depending on the type of UAV or UCAV. Jet powered attack aircraft will benefit the least from this, while glider like scouts or surveillance aircraft would benefit the most):

http://nextbigfuture.com/2013/03/dynamic-soaring-and-riding-rising.html#more

Dynamic Soaring and Riding Rising Thermal Air Currents for Super Endurance Robotic Gliding

  Wandering albatrosses exploit the vertical gradient of wind velocity (wind shear) above the ocean to gain energy for long distance dynamic soaring with a typical airspeed of 36 mph. In principle, albatrosses could soar much faster than this in sufficient wind, but the limited strength of their wings prevents a much faster airspeed. Recently, pilots of radio-controlled (RC) gliders have exploited the wind shear associated with winds blowing over mountain ridges to achieve very fast glider speeds, reaching a record of 498 mph in March 2012. A relatively simple two-layer model of dynamic soaring predicts maximum glider airspeed to be around 10 times the wind speed of the upper layer (assuming zero wind speed in the lower layer). This indicates that a glider could soar with an airspeed of around 200 mph in a wind speed of 20 mph, much faster than an albatross. It is proposed that recent high performance RC gliders and their pilots’ expertise could be used to develop a high-speed robotic albatross UAV (Unmanned Aerial Vehicle), which could soar over the ocean like an albatross, but much faster than the bird. This UAV could be used for various purposes such as surveillance, search and rescue, and environmental monitoring. A first step is for pilots of RC gliders to demonstrate high-speed dynamic soaring over the ocean in realistic winds and waves.

The hand-launched Tactical Long Endurance Unmanned Aerial System (TALEUAS) is being developed at the Unites States’ Naval Postgraduate School in Monterey, California. It needs an electric propeller to get airborne, but give it a few minutes to reach a reasonable altitude and TALEUAS can fly all day just by riding rising currents of warm air called thermals.

When TALEUAS encounters a thermal it senses the lift and spirals around to take advantage of it. Vultures and eagles use the same technique, and Kevin Jones, who is in charge of the project, says he has often found TALEUAS sharing the air with these raptors. On some occasions, indeed, the birds found that the thermals they were attempting to join it in were too weak for their weight, as the drone is more efficient than they are at gliding.

TALEUAS’s endurance is limited only by the power requirements of its electronics and payload, for at the moment these are battery powered. Dr Jones and his team are, however, covering the craft’s wings with solar cells that will generate power during the day, and are replacing its lithium-polymer battery with a lithium-ion one capable of storing enough energy to last the night. That done, TALEUAS will be able to stay aloft indefinitely.

TALEUAS does, however, depend on chance to locate useful thermals in the first place. Roke Manor Research, a British firm, hopes to eliminate that element of chance by allowing drones actively to seek out rising air in places where the hunt is most likely to be propitious. As well as thermals, Mike Hook, the project’s leader, and his team are looking at orographic lift, produced by wind blowing over a ridge, and lee waves caused by wind striking mountains. Their software combines several approaches to the search for rising air. It analyses the local landscape for large flat areas that are likely to produce thermals, and for ridges that might generate orographic lift. It also employs cameras to spot cumulus clouds formed by rapidly rising hot air. Such software replicates the behaviour of a skilled sailplane pilot—or a vulture—in knowing where to find rising air and where to avoid downdraughts.
 
http://www.fmv.se/sv/Nyheter-och-press/Nyheter-fran-FMV/Hoppande-handgranat/

There is a video posted on the website

Jumping grenade reduces the risk of innocent people being injured in war

A FMV-employed engineer behind the biggest news in the grenade area since WWI. By jumping up just before brisaden and direct shrapnel in a cone down to the ground minimizes the risk of innocent victims, while the grenade is many times more effective against their military objectives.
When an ordinary shrapnel grenade explodes, half of shrapnel into the ground to no value. The other half goes into the air, spreading in all directions and involves unnecessary danger to a third party. Only a few fragments have a chance to give effect to the target, provided that no soldier behind a small barrier, then no effect correctly.

- I started this because I did not like the usual grenades turned its function. They are unnecessarily hazardous to innocents around and they do not generally able to achieve the goal, says Ian Kinley, technical expertise in specialized munitions at FMV.

Ian Kinleys solution is based instead on the grenade suspends himself in the air before it explodes.

- Because it defers to reach not only targets behind obstacles. The actual technology behind the launch means that it knows what is up and down, which allows us to target shrapnel downwards, in an area five meters around the crash site, said Ian Kinley.
More on link
 
Repost, sorry:
http://forums.army.ca/forums/threads/91633/post-1203232.html#msg1203232
 
Batteries and energy supply is one of the key limiting factors in military logistics. The size, weight and number of batteries that an individual soldier needs to carry is pretty astounding (everything from AAA batteries for the head lamp to military batteries for the radio, DAGR, thermal imager etc.). Next on the food chain is the need to carry all these different batteries and either charge them or replace them as they die.

This is a promising technology that has the potential to shrink batteries and store energy at much higher densities than were posible before (starting a car on a battery the size of a cell phone battery?). This will certainly make the logistical issues much simpler:

http://news.illinois.edu/news/13/0416microbatteries_WilliamKing.html

Small in size, big on power: New microbatteries a boost for electronics

4/16/2013 | Liz Ahlberg, Physical Sciences Editor | 217-244-1073; eahlberg@illinois.edu

CHAMPAIGN, Ill. — Though they be but little, they are fierce. The most powerful batteries on the planet are only a few millimeters in size, yet they pack such a punch that a driver could use a cellphone powered by these batteries to jump-start a dead car battery – and then recharge the phone in the blink of an eye.

Mechanical science and engineering professor William P. King led a group that developed the most powerful microbatteries ever documented.  | Photo by L. Brian StaufferDeveloped by researchers at the University of Illinois at Urbana-Champaign, the new microbatteries out-power even the best supercapacitors and could drive new applications in radio communications and compact electronics.

Led by William P. King, the Bliss Professor of mechanical science and engineering, the researchers published their results in the April 16 issue of Nature Communications.

“This is a whole new way to think about batteries,” King said. “A battery can deliver far more power than anybody ever thought. In recent decades, electronics have gotten small. The thinking parts of computers have gotten small. And the battery has lagged far behind. This is a microtechnology that could change all of that. Now the power source is as high-performance as the rest of it.”

With currently available power sources, users have had to choose between power and energy. For applications that need a lot of power, like broadcasting a radio signal over a long distance, capacitors can release energy very quickly but can only store a small amount. For applications that need a lot of energy, like playing a radio for a long time, fuel cells and batteries can hold a lot of energy but release it or recharge slowly.

“There’s a sacrifice,” said James Pikul, a graduate student and first author of the paper. “If you want high energy you can’t get high power; if you want high power it’s very difficult to get high energy. But for very interesting applications, especially modern applications, you really need both. That’s what our batteries are starting to do. We’re really pushing into an area in the energy storage design space that is not currently available with technologies today.”

The new microbatteries offer both power and energy, and by tweaking the structure a bit, the researchers can tune them over a wide range on the power-versus-energy scale.

The batteries owe their high performance to their internal three-dimensional microstructure. Batteries have two key components: the anode (minus side) and cathode (plus side). Building on a novel fast-charging cathode design by materials science and engineering professor Paul Braun’s group, King and Pikul developed a matching anode and then developed a new way to integrate the two components at the microscale to make a complete battery with superior performance.

With so much power, the batteries could enable sensors or radio signals that broadcast 30 times farther, or devices 30 times smaller. The batteries are rechargeable and can charge 1,000 times faster than competing technologies – imagine juicing up a credit-card-thin phone in less than a second. In addition to consumer electronics, medical devices, lasers, sensors and other applications could see leaps forward in technology with such power sources available.

“Any kind of electronic device is limited by the size of the battery – until now,” King said. “Consider personal medical devices and implants, where the battery is an enormous brick, and it’s connected to itty-bitty electronics and tiny wires. Now the battery is also tiny.”

Now, the researchers are working on integrating their batteries with other electronics components, as well as manufacturability at low cost.

“Now we can think outside of the box,” Pikul said. “It’s a new enabling technology. It’s not a progressive improvement over previous technologies; it breaks the normal paradigms of energy sources. It’s allowing us to do different, new things.”

The National Science Foundation and the Air Force Office of Scientific Research supported this work. King also is affiliated with the Beckman Institute for Advanced Science and Technology; the Frederick Seitz Materials Research Laboratory; the Micro and Nanotechnology Laboratory; and the department of electrical and computer engineering at the U. of I.

Editor's note: To reach William King, call 217-244-3864; email wpk@illinois.edu.

The paper, “High Power Lithium Ion Micro Batteries From Interdigitated Three-Dimensional Bicontinuous Nanoporous Electrodes,” is available online.
 
This technology may also have application in diagnosing and healing brain injuries (and the potential to overcome nerve damage injuries as well). Some of the other potential applications are a bit bizzare or disturbing; being able to modify behaviour is certainly something with huge moral implications:

http://spectrum.ieee.org/biomedical/devices/injectable-optoelectronics-for-brain-control/

Injectable Optoelectronics for Brain Control
Device lets neuroscientists perform optogenetics experiments wirelessly

By Prachi Patel  /  April 2013
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Implantable Optoelectronics: A flexible system that includes electrodes, LEDs, photodetectors, and a temperature sensor were designed to be implanted in an animal’s brain and wirelessly controlled via an RF receiver affixed to the animal’s skull.
Photo: University of Illinois-Urbana Champaign and Washington University-St. Louis Implantable Optoelectronics: A flexible system that includes electrodes, LEDs, photodetectors, and a temperature sensor were designed to be implanted in an animal’s brain and wirelessly controlled via an RF receiver affixed to the animal’s skull.

Optogenetics, a recently developed technique that uses light to map and control brain activity, requires the genetic modification of an animal’s brain cells and the insertion of optical fibers and electrical wire into its brain. The bulky wires and fibers emerge from the skull, hampering the animal’s movement and making it difficult to perform certain experiments that could lead to breakthroughs for Parkinson’s disease, addiction, depression, and spinal cord injuries.

But now, a new ultrathin, flexible device laden with light-emitting diodes and sensors, both the size of individual brain cells, promises to make optogenetics completely wireless. The 20-micrometer-thick device can be safely injected deep into the brain and controlled and powered using radio-frequency signals. Its developers say the technology could also be used in other parts of the body, with broad implications for medical diagnosis and therapy.

In optogenetics, scientists genetically modify neurons to make them sensitive to particular wavelengths of light. Shining light on the altered neurons turns them on or off, allowing scientists to control specific brain circuits and change animal behavior.

Michael Bruchas, a neurobiologist at Washington University, in St. Louis, wanted to develop a wireless alternative to the fiber-optic approach. “Wires limit the animal’s natural behavior,” he says. “We couldn’t explore some experiments with the animals tethered, say, if we want two animals interacting or want them to be in a naturalistic environment.” So he teamed up with John Rogers at the University of Illinois at Urbana-Champaign to design a new system based on extremely thin semiconductor devices. The researchers published their results in this week’s issue of the journal Science.
Implantable Optoelectronics: A flexible system that includes electrodes, LEDs, photodetectors, and a temperature sensor were designed to be implanted in an animal’s brain and wirelessly controlled via an RF receiver affixed to the animal’s skull.
Photo: University of Illinois-Urbana Champaign and Washington University-St. Louis

The implant is a stack of four different optoelectronics devices that the researchers create separately on flexible polymer substrates and then glue on top of one another. The topmost layer is a platinum microelectrode for stimulating and recording from neurons. Below that is a silicon photodetector, followed by a group of four microscale LEDs that are each just 50 by 50 micrometers. Last comes a platinum-based temperature sensor. The filament carrying the stack is glued onto a microneedle with a silk-based glue that dissolves once the device has been injected into the targeted spot, allowing the researchers to retract the microneedle.

The technique for making the membranous devices is not new. Developed a few years ago in Rogers’s lab, it involves growing stacks of thin semiconductor films, peeling them off one at a time with a rubber stamp, and transferring them to plastic substrates.

Scientists could use the multifunctional system to stimulate and sense the brain in a variety of ways, Bruchas explains. The microelectrode can measure the electrical signals produced by neurons, and it can also be used to stimulate them. The photodiodes ensure that the LEDs are working, but they can also be used to detect light signals generated by neurons that have been genetically modified to make certain fluorescent proteins.

The micro-LEDs, which have dimensions comparable to individual neurons, could trigger individual neurons, unlike the fiber-optic implants typically used in optogenetics, which are four times as wide. The researchers could also combine different-colored LEDs on the same device and use them to simultaneously control neurons that have been engineered to react to different colors. Such multiplexing would allow neuroscientists to analyze brain circuits more precisely, Bruchas says. Finally, the temperature sensor monitors the heat generated by the LEDs to prevent the tissue from overheating.

When the researchers placed the device—which connects to an RF power module mounted on the animal’s head—inside the brains of living mice, it caused no inflammation or infection. To test the system’s ability to alter animal behavior, the researchers embedded it near a particular group of neurons that they had genetically altered to release dopamine when cued with light. The neurochemical dopamine is involved in the body’s “rewards” system, such as with food or sex, and it plays a part in several addictive drugs.

In this experiment, the mice were placed in a maze. When the animals reached a particular place in the maze, the researchers wirelessly pulsed the LEDs on and off, triggering the release of dopamine. The animals quickly learned to go to that spot for the pleasure sensation.

“The device illustrates the integration of miniaturized semiconductor devices deep within tissue, be it brain or the heart or any other organ,” Rogers says. More-sophisticated silicon-based microcircuits could be implanted in the future, he says, paving the way for applications in medical diagnosis, monitoring, and treatment.

The work “shows how miniaturization and systems integration guide us toward novel devices and applications,” says Thomas Stieglitz, a professor in the department of microsystems engineering at the University of Freiburg, in Germany. Stieglitz and his colleagues are also trying to develop a wireless, possibly biodegradable, implant for optogenetics.

“The ability to perform wireless stimulation and sensing is going to open up new doors for behavioral neuroscience, allowing the study of more complex behaviors, such as social interaction and mating behaviors,” says Kay Tye, a professor of neuroscience at MIT.
About the Author

Prachi Patel is a contributing editor to IEEE Spectrum. In February 2013, she reported on another optogenetics advance.
 
Everyone loves touchscreens on devices ranging from smarphones to display screens, but they are bloody expensive as you go up in size. This is an inexpensive way to change that and convert existing screens into interactive display units. Now you really will be able to use interpretive dance while you do a briefing  ;)

http://www.technologyreview.com/news/514061/a-simple-way-to-turn-any-lcd-into-a-touch-screen/

A Simple Way to Turn Any LCD into a Touch Screen
Electromagnetic interference can turn a plain LCD into a touch screen on the cheap.

By Rachel Metz on April 24, 2013
WHY IT MATTERS

It’s cheaper and less wasteful to modify an existing screen than it is to replace it.

Electromagnetic interference can screw up cell phone and radio reception. But it may also be the key to cheaply transforming regular LCD screens into touch- and gesture-sensing displays, according to recent research.

A group of researchers from the University of Washington’s Ubiquitous Computing Lab developed a method called uTouch that uses a simple sensor and software to turn an ordinary LCD into a touch screen display. The system takes advantage of the low levels of electromagnetic interference produced by many consumer electronics, harnessing it to do things like control video playback with pokes and motions on an otherwise noninteractive screen.

“All these devices around you have all these signals coming out of them, and we ignore them because we think they’re noise,” says Sidhant Gupta, a PhD candidate at the University of Washington’s Ubiquitous Computing Lab and one of the co-authors of the paper.

While touch screens are the norm on smartphones and tablets, they’re still not common on TVs, computer monitors, and other big displays. Existing methods that turn passive LCDs into touch screens typically use cameras or other sensors, but they’re not always practical. The group’s findings, explained in a paper that will be presented in May at the Computer Human Interaction conference in Paris, could eventually be used to cheaply add touch and gesture interactions to TVs, computers, and much larger displays, too.

Gupta says his group’s method works by measuring signals that are normally given off by an LCD display and how they change when a user brings a hand near the screen. These signals show up as electromagnetic interference, and can be measured with a $5 sensor that plugs into a wall outlet.

In the study, users’ gestures and touches controlled an on-screen video player. Information about how the user’s actions changed the LCD’s electromagnetic interference was gathered by the sensor, and then sent to a connected PC, where software isolated the display’s signal and tracked how it changed over time. The software used machine learning to predict if changes were simply “noise” or one of five gestures and touches that it had been set to respond to. Once the touch or gesture was determined, it would elicit an appropriate on-screen response—like pausing or resizing a video.

“What we’re trying to find out is how that signal changes, and in particular we’re looking for changes in the intensity of that signal,” Gupta says.

The system can tell the difference between different displays, since each has its own electromagnetic interference “fingerprint,” and a single sensor can be used to track interactions on numerous displays. Eventually, Gupta says, the sensing and processing could be done in a single unit that’s plugged into a wall socket.

The technology won’t make a noninteractive display as touch-sensitive as an iPhone or Android smartphone. The gestures are much simpler than the complex swipes and pinches you can make on those gadgets.

Still, Gupta can imagine it being used to do things like make large screens at museums interactive. It could also be used to add interactivity to other devices that emit electromagnetic interference—something Gupta and some of his uTouch colleagues explored in an earlier project called LightWave that uses a plug-in sensor to enable compact fluorescent lightbulbs to sense human proximity.

“The more things we can make interactive that already exist, the better,” says Chris Harrison, cofounder of a startup whose touch-screen technology can tell the difference between fingernail and knuckle taps and a PhD candidate at Carnegie Mellon University’s Human-Computer Interaction Institute. “It’s very expensive to just put touch screens everywhere.”

The researchers aren’t planning to commercialize the technology, but Gupta says the sensor uses off-the-shelf parts, and the algorithms are included in the paper, so any motivated person could put together the same system.

The challenge to building interest, Harrison thinks, will be in refining the gestures that uTouch can understand—which are currently quite coarse—and finding the right applications. “You could never write an e-mail with this system, but you could do some cool gestural interactions,” he says.
 
This is a technology that can be retrofitted to almost any vehicle in the fleet. The flywheel can provide a burst of energy to accelerate or pull out of terrain like sand or mud, as an alternative to using it to save fuel. Some resetting of the control electronics would be needed to bias it towards power vs economy, but otherwise the system would not change:

http://nextbigfuture.com/2013/04/volvo-kers-flywheel-system-boosts-fuel.html

Volvo Kers Flywheel System boosts fuel efficiency by 25% and will look to put it into production cars

Volvo Car Group has completed extensive testing of kinetic flywheel technology on public roads - and the results confirm that this is a light, cheap and very eco-efficient solution.

"The testing of this complete experimental system for kinetic energy recovery was carried out during 2012. The results show that this technology combined with a four-cylinder turbo engine has the potential to reduce fuel consumption by up to 25 per cent compared with a six-cylinder turbo engine at a comparable performance level," says Derek Crabb, Vice President Powertrain Engineering at Volvo Car Group, "Giving the driver an extra 80 horsepower, it makes car with a four-cylinder engine accelerate like one with a six-cylinder unit."

The experimental system, known as Flywheel KERS (Kinetic Energy Recovery System), is fitted to the rear axle. During retardation, the braking energy causes the flywheel to spin at up to 60,000 revs per minute. When the car starts moving off again, the flywheel's rotation is transferred to the rear wheels via a specially designed transmission.

The stored energy was sufficient to power the car for short periods, meaning the engine could be switched off for as much as 50 percent of the time.

Compared to a conventional gasoline-electric hybrid, Volvo’s flywheel KERS is lighter, cheaper and easier to maintain.

The flywheel that Volvo Cars used in the experimental system is made of carbon fibre. It weighs about six kilograms and has a diameter of 20 centimetres. The carbon fibre wheel spins in a vacuum to minimise frictional losses.

"We are the first manufacturer that has applied flywheel technology to the rear axle of a car fitted with a combustion engine driving the front wheels. The next step after completing these successful tests is to evaluate how the technology can be implemented in our upcoming car models," concludes Derek Crabb.


 
An interesting way to make fiber based materials "tougher" (this is not the same as "Stronger", as explained in the article):

http://www.technologyreview.com/view/514316/simple-trick-turns-commercial-polymer-into-worlds-toughest-fiber/

Simple Trick Turns Commercial Polymer Into World's Toughest Fiber
April 29, 2013
Simple Trick Turns Commercial Polymer Into World’s Toughest Fiber
A materials scientist has created the world’s toughest fiber using a mechanism based on a slip knot.

In material science, toughness is a measure of the amount of energy a material can absorb before breaking. Kevlar, for example, can absorb some 80 Joules per gram before breaking but this is dwarfed by certain natural materials which are much tougher. The silk produced by the giant riverine orb spider, for instance, can absorb around 390 Joules per gram before breaking.

So there is great interest in finding new materials that can match or beat the performance of natural materials for applications that require high levels of energy absorption.

Today, Nicola Pugno at the University of Trento in Italy reveals a remarkably simple trick that dramatically increases the toughness of almost any kind of fibre. Indeed, Pugno says he has used the technique to create the world’s toughest fibre.

The new idea is deceptively simple–it involves no more than tying a slip knot in the fibre, creating a loop of extra fibre that can passes through the knot as it comes under tension.

The mechanism is straightforward. When the fibre is placed in tension, the slip knot begins to tighten and the extra material passes through the knot, dissipating energy through friction. 

Of course, the fibre eventually breaks but only after all the material in the loop has passed through the slip knot.

Clearly this doesn’t make the material any stronger (toughness and strength are different properties that are generally uncorrelated). However, it’s not hard to see how the energy dissipation would dramatically increase the amount of energy the fibre absorbs before it breaks, thereby increasing its toughness.

Pugno says he has tested the idea on a number of materials using different numbers of loops and slip knots. The best results come from using three slip knots, he says.

By applying this simple trick to a commercial polymer fibre called Endumax, he has increased its toughness from 44 Joules per gram to a remarkable 1070 Joules per gram. That’s the highest value ever recorded. “The proof of concept is experimentally realized making the world’s toughest fibre,” he says.

That’s better even than fibres made from nanotubes which materials scientists are just beginning to make. The strongest of these, made from carbon nanotubes, has a toughness of 970 Joules per gram.

Pugno says his work is just the beginning and that it ought to be possible to use his slip-knot technique to make graphene fibres with a toughness of 100,000 Joules per gram.

There are challenges ahead, of course. Ideally, the force required to pass the fibre through the knot should be just below the material’s breaking point and this depends on factors such as the knot topology. The choice of knot has an important influence on the behaviour of the material and further work here could lead to novel designs. Pugno says he is currently patenting his slip-knot design and so has not yet published it.

The potential applications of this idea are many. Tougher materials could obviously be used in areas where energy absorption is important, such as the manufacture of body armour, for example.

That’s an effective and cheap idea that has significant potential. It’s also extraordinarily simple, which might just be the reason it has been overlooked until now.

Ref: arxiv.org/abs/1304.6658: The “Egg of Columbus” For Making The World’s Toughest Fibres
 
It wasn't that many years ago a machine with this performance was an expensive Server device. Now for $45, you can get the same sort of performance in a credit card sized board....

Building "smart" devices or expanding "clouds" of computers becomes ridiculously easy as the costs of hardware and software decline and the availability increases:

http://www.eetimes.com/electronics-blogs/semi-conscious/4413238/BeagleBone-Black--A-1-GHz-computer-for--45

BeagleBone Black: A 1-GHz computer for $45
Dylan McGrath
5/2/2013 1:24 AM EDT
One of the most interesting demos at last week's DESIGN West conference was BeagleBone Black, a ready-to-use 1-GHz computer that retails for a whopping $45.

BeagleBone Black was announced last week by BeagleBoard.org, a small group of engineers interested in creating powerful, open and embedded devices. The credit card sized computer runs on Linux and is designed to be an open hardware and software development platform that makes it quick and easy to build systems.

BeagleBone Black includes all the necessary components to connect a display, keyboard and network. It's based on production-ready hardware and software. All of the components—including TI’s 1-GHz Sitara AM335x processor—are commercially available right now.

Carlos Betancourt, a marketing engineer for TI's Sitara processors, described BeagleBone Black as "truly" open source. He noted that open source software is not always as open as it claims to be. "When it comes to hardware, open source means you can buy all these chips and use them for your own design," Betancourt said.

BeagleBone Black includes 2 GB of on-board storage to run pre-loaded Linux software. It also offers the Cloud9 integrated development environment to kickstart development and keep the microSD slot available for additional storage.

The BeagleBoard.org ecosystem includes free access to documentation, example code and mainline kernel support for other software distributions like Ubuntu, Android and Fedora. BeagleBone Black’s kernel and driver flexibility allows users to easily integrate new hardware and software, according to the organization.

In BeagleBoard.org community includes more than 30 plug-in boards—called “capes” by the community—that are compatible with BeagleBone Black, including those to integrate BeagleBone Black with 3-D printers, a DMX lighting controller, a Geiger counter, a telerobotic submarine and LCD touch screens. More are on the way.

Do you have a creative project idea that can help change the world? Make it a reality by ordering BeagleBone Black now. A list of distributors is available at www.beagleboard.org/black. Initial quantities are limited.  BeagleBone Black is expected to ship in volume by the end of May.

BeagleBone Black can be ordered, among other places, on TI's website. A complete list of distributors can be found on Beagleboard.org's website.
 
Seems the US Navy was taking notes when the 3D printer gun debuted very recently...

Gizmodo Link

Navy Wants Aircraft Carriers to Manufacture Weapons On the Go

Kelsey Campbell-Dollaghan Today 10:17amg 25,099L 93

These days, the mention of 3D-printed weapons conjures up visions of people printing AK-47s in their garages (ok, that might just be me). But a recent story in the Armed Forces Journal brings word of a more systematic implementation of 3D-printed warfare.

According to one Lieutenant Commander Michael Llenza, the Navy's future lies in converting aircraft carriers into “floating factories,” each carrying a fleet of 3D printers to churn out weapons, drones, and even shelters at a moment’s notice. There’s money and time to be saved in the sheer logistical rationality of the scheme. For example, when cylindrical bullets are stacked, tiny bits of wasted space are created—which add up, when you're talking about millions of the things. Rectangular packages of powder, which could be printed into bullets when needed, are a far more efficient use of space.

Right now, research on such a scheme is being done in bits and pieces. Llenza points out a handful of examples, including Contour Crafting, the building-sized 3D printing system, as well as several recent projects in which complete UAVs were produced overnight:


[…] The University of Virginia printed a UAV controlled by a relatively cheap Android phone whose camera was used to shoot aerial imagery. Designed for a top speed of 45 mph, the aircraft crashed on its first flight. The students just went back to the lab and printed out a replacement nose cone, a capability envied by any squadron maintenance officer. The eventual goal is a drone that flies right out of the printer with electronics and motive power already in place. An organic ability to print replaceable drones from ships, forward operating bases or during disaster relief operations to serve as targets or observation platforms could be a huge enabler for sailors and Marines.

Of course, there are still huge gaps to be bridged, technologically speaking, before 3D printing can be adopted as a large-scale military inventory strategy. It’s supremely expensive right now, and more importantly, the structural stability of many materials is inconsistent—so replacing critical pieces of machinery is out of the question. Still, it’s an exciting idea, especially when you see it in the terms laid out by MIT’s Neil Gershenfeld, who describes the 3D printing as the ability to “turn data into things and things into data.” Llenza sums it up nicely by wondering how much simpler Apollo 13's mission would have been, had the crew been able to simply request the appropriate CAD model from ground control. [Armed Forces Journal via ExtremeTech]
 
Graphene (and related monomolecular films like "silicene ", the Silicon analogue of Graphine) can now be fabricated in large sheets. The implications of this are astounding (sheets of graphine are as strong as diamond but weigh only a few grams/m^2, and have interesting electrical properties as well):



High-Strength Chemical-Vapor–Deposited Graphene as large as TV screens produced that are 90% as strong as ideal crystal graphene
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In a new study, published in Science May 31, 2013, Columbia Engineering researchers demonstrate that graphene, even if stitched together from many small crystalline grains, is almost as strong as graphene in its perfect crystalline form. This work resolves a contradiction between theoretical simulations, which predicted that grain boundaries can be strong, and earlier experiments, which indicated that they were much weaker than the perfect lattice. Scientists can grow sheets of graphene as large as a television screen by using chemical vapor deposition (CVD), in which single layers of graphene are grown on copper substrates in a high-temperature furnace. One of the first applications of graphene may be as a conducting layer in flexible displays. The graphene has a strength of 95 gigapascals. It has 90% of the strength of perfect molecular graphene and is stronger than molecular carbon nanotubes.

This is a huge step towards an age of super materials with constructs like space elevators. This still needs to be industrialized with production of thousands to millions of tons per year.

The Columbia Engineering team wanted to discover what was making CVD graphene so weak. In studying the processing techniques used to create their samples for testing, they found that the chemical most commonly used to remove the copper substrate also causes damage to the graphene, severely degrading its strength.

Their experiments demonstrated that CVD graphene with large grains is exactly as strong as exfoliated graphene, showing that its crystal lattice is just as perfect. And, more surprisingly, their experiments also showed that CVD graphene with small grains, even when tested right at a grain boundary, is about 90% as strong as the ideal crystal.
Large Graphene sheets with over 95 Gigapascals of strength were produced. Perfect graphene has 105 gigapascals of strength


Pristine graphene is the strongest material ever measured. However, large-area graphene films produced by means of chemical vapor deposition (CVD) are polycrystalline and thus contain grain boundaries that can potentially weaken the material. We combined structural characterization by means of transmission electron microscopy with nanoindentation in order to study the mechanical properties of CVD-graphene films with different grain sizes. We show that the elastic stiffness of CVD-graphene is identical to that of pristine graphene if postprocessing steps avoid damage or rippling. Its strength is only slightly reduced despite the existence of grain boundaries. Indentation tests directly on grain boundaries confirm that they are almost as strong as pristine. Graphene films consisting entirely of well-stitched grain boundaries can retain ultrahigh strength, which is critical for a large variety of applications, such as flexible electronics and strengthening components.



“This is an exciting result for the future of graphene, because it provides experimental evidence that the exceptional strength it possesses at the atomic scale can persist all the way up to samples inches or more in size,” says Hone. “This strength will be invaluable as scientists continue to develop new flexible electronics and ultrastrong composite materials.”

Strong, large-area graphene can be used for a wide variety of applications such as flexible electronics and strengthening components—potentially, a television screen that rolls up like a poster or ultrastrong composites that could replace carbon fiber. Or, the researchers speculate, a science fiction idea of a space elevator that could connect an orbiting satellite to Earth by a long cord that might consist of sheets of CVD graphene, since graphene (and its cousin material, carbon nanotubes) is the only material with the high strength-to-weight ratio required for this kind of hypothetical application.

The team is also excited about studying 2D materials like graphene. “Very little is known about the effects of grain boundaries in 2D materials,” Kysar adds. “Our work shows that grain boundaries in 2D materials can be much more sensitive to processing than in 3D materials. This is due to all the atoms in graphene being surface atoms, so surface damage that would normally not degrade the strength of 3D materials can completely destroy the strength of 2D materials. However with appropriate processing that avoids surface damage, grain boundaries in 2D materials, especially graphene, can be nearly as strong as the perfect, defect-free structure.”
 
Getting high bandwidth comms out to remote places or where the infrastructure is destroyed/unavailable is a difficult task. Google may have found an inexpensive way to do this (and either free flying or teathered ballons might do the same for us):

http://nextbigfuture.com/2013/06/google-project-loon-deploying-high.html

Google Project Loon deploying high altitude balloons to provide internet access to everyone

Introducing the latest moonshot from Google[x]: balloon-powered Internet access. Project Loon is a network of balloons traveling on the edge of space, designed to connect people in rural and remote areas, help fill in coverage gaps and bring people back online after disasters.

Many of us think of the Internet as a global community. But two-thirds of the world’s population does not yet have Internet access. Project Loon is a network of balloons traveling on the edge of space, designed to connect people in rural and remote areas, help fill coverage gaps, and bring people back online after disasters.

Project Loon balloons travel around 20 km above the Earth’s surface in the stratosphere. Winds in the stratosphere are generally steady and slow-moving at between 5 and 20 mph, and each layer of wind varies in direction and magnitude. Project Loon uses software algorithms to determine where its balloons need to go, then moves each one into a layer of wind blowing in the right direction. By moving with the wind, the balloons can be arranged to form one large communications network.

They use “variable buoyancy”—steering the balloons by tweaking altitude to find wind currents whooshing in the right direction. Google, which is pretty good at computation, could use the voluminous government data available to accurately simulate wind currents in the stratosphere.

The Project Loon pilot test begins June 2013 on the 40th parallel south. Thirty balloons, launched from New Zealand’s South Island, will beam Internet to a small group of pilot testers. The experience of these pilot testers will be used to refine the technology and shape the next phase of Project Loon.

The balloon envelope is the name for the inflatable part of the balloon. Project Loon’s balloon envelopes are made from sheets of polyethylene plastic and stand fifteen meters wide by twelve meters tall when fully inflated. They are specially constructed for use in superpressure balloons, which are longer-lasting than weather balloons because they can withstand higher pressure from the air inside when the balloons reach float altitude. A parachute attached to the top of the envelope allows for a controlled descent and landing whenever a balloon is ready to be taken out of service.

Googlers in fleece and down vests scurry around a huge tarp, ministering to five “envelopes”—the term for the high-tensity, polyethylene balloons—resting on red plastic covers. The envelopes seem no more glamorous than long garbage bags and, indeed, at three-thousands of an inch thick, not even a premium brand. But the high-tech polyethylene can in fact stave off tremendous pressure.

Attached to the bottom of each envelope is the 22-pound “payload.” It’s topped by a sheet of solar paneling the size of a basketball backboard. Beneath the solar sheet is a construct resembling a large camera tripod, whose legs are antennas that allow the balloons to transmit to their peers in a mesh network. And on the bottom of the structure is a metal-sided container resembling a deep fuse box, which contains the computers, electronics, GPS devices, and batteries to store the energy gathered by the solar panels (each about 10 times the size of a laptop battery). It also controls valves that go inside the balloon’s internal chambers, allowing the balloon to find the desired altitude to maintain its flight path. Dangling from the box is a cable ending in a piece of foam that looks like a slice of a kid’s swimming noodle; inside is a transponder that beams location to air-traffic controllers and other trackers.

It’s time to launch. As team members take positions to stabilize and hold down the balloon, a machine that seems an artifact from the industrial age begins pumping helium into an envelope with a sound like a thousand hot showers channeled through Jimi Hendrix’s amps. And the clear plastic starts to rise. A blob-ish lump awakens inside the balloon skin, quickly growing from waist level to three times human height. As more gas enters, a classic balloon, like Dorothy’s vehicle to Oz, takes shape, at first looking like a giant pumpkin, then resembling a swimming jellyfish, straining for the ocean surface.

The flight engineer organizing the launch begins a classic NASA-esque backwards countdown, and chatter subsides as the numbers decline. At zero, a Googler holding a yellow sheet of matting called “the peanut”—it’s wrapped around the neck of the balloon to keep the payload from dangling during inflation—lets go. The mass jumps skyward, tugging the payload off the ground. It rises nimbly and steadily, and soon it’s hard to tell the difference between this giant translucent mass (a Loon balloon will grow to the size of a small aircraft) and a child’s toy floating above rooftop level.
 
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