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European VC Funding Reached 13-Yr High In 2014

A week ago, we reported that venture funding for U.S. startups is booming. Turns out, the good news isn’t for U.S. startups alone. European VC investment was also at its highest in 2014 since the dot-com boom.

According to data published this week by Dow Jones VentureSource, European startups raised $8.9 billion (€7.9 billion) last year across 1460 deals, up from €6.3 billion in 2013. That’s the largest investment since 2001, when European ventures secured €10.6 billion.

The funds are going predominantly to tech startups. And most of them are in the United Kingdom and Germany. London and Berlin are Europe’s fastest growing tech hubs, teeming with companies setting up offices in converted warehouses and startup lofts. Tech companies in London raised $1.4 billion and those in Berlin secured $1.1 billion, according to the research company CB Insights.

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Silk Implants Fight Bacterial Infection Then Vanish


A new electronic implant can fight bacterial infection inside the body and then harmlessly dissolve. The simple, passive device is made entirely of silk and magnesium, which are both benign, biocompatible materials. The device, which can be loaded with antibiotics, could be implanted inside the body during surgery and then wirelessly triggered from outside to kill bacteria using heat or by releasing drugs. Once its work is done, it would dissolve.

The idea is to make benign, functional electronics that last in the body for a finite amount of time so that no surgical retrieval is required, explains Fiorenzo Omenetto, a professor of bioengineering at Tufts University. Researchers from Omenetto’s group, together with collaborators from the Shanghai Institute of Microsystem and Information Technology in China and the University of Illinois at Urbana-Champaign, presented results on their device at the IEEE MEMS 2015 conference last week.

Several other research teams are exploring the potential of spider silk for electronics. Omenetto focuses on silkworm silk. In addition to vanishing medical implants, he wants to make silk-based consumer electronics that would degrade when needed rather than lying around in landfills. He has made graphene-and-silk-based nanosensing tattoos to detect bacteria in the mouth. And with UIUC’s John Rogers, he has previously made silk-encased dissolvable electronics that used silicon nanomembranes as the electronics substrate.

The device that the researchers presented at MEMS 2015—and recently in the journal PNAShas no silicon. It’s a very simple design: a power-receiving coil and a serpentine resistor made of magnesium are deposited on a silk film and then encapsulated in a silk pocket. Omenetto’s team gets the silk from silkworm cocoons. They’ve figured out how to fine-tune the silk’s crystallinity and other properties so that it degrades at time intervals ranging from minutes to weeks.

“You then have a little band-aid that you put under the skin,” Omenetto says. “Silk here acts like the plastic substrate, and it is medically digestive. And the magnesium on top hydrolyzes and breaks down and dissolves.”

The researchers implanted the device in the skin of mice that were infected with the Staphylococcus aureus bacteria. They wirelessly activated the device using a transmitter for two sets of ten-minute treatments. The resistor heats up, and the heat kills bacteria. After 24 hours, tissue collected from the mice was infection-free. The device fully dissolved and vanished in 15 days.

In a separate in vitro experiment, the researchers loaded a silk film with the antibiotic ampicillin and attached it, along with a magnesium heater, to a silk pocket. When they wirelessly heated the device, the silk film released the drug.

Photo: Tufts University

Skin-Based Generators Scavenge Muscle Motion to Power Wearables

Using human skin as one of its charge-collectors, a new flexible generator converts muscle movements into enough power for small electronics. The postage-stamp-sized device takes advantage of static electricity to convert mechanical energy into electrical energy.

Such friction-powered generators could usher new types of wearable sensors that don’t require batteries but instead are powered by the wearer’s daily activities like walking, talking or holding an object.

The new device, which researchers from the National University of Singapore presented at the IEEE MEMS 2015 conference last week, can generate 90 volts of open circuit voltage when touched gently with a finger. Electrical and computer engineering professor Chengkuo Lee and his colleagues demonstrated that the new device can be used as a wearable self-powered sensor to track the user’s motion and activity.

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When U.S. Telecoms Come Calling, Will Cuba Pick Up The Phone?

This month, U.S. President Barack Obama’s administration began opening the long-closed diplomatic door to Cuba. Among other things the President's plan makes way for is the ability of U.S. companies to sell telecommunications equipment to the island. Legislation imposing a broad economic embargo still stands, but the administration has some leeway over activity that improves the flow of information under the banner of “spreading democracy.”

(Exceptions to the old embargo abound: the U.S. National Science Foundation actually provided Cuba’s first Internet connection in 1996 as part of a broader connectivity drive for developing countries.)

What remains unclear, says computer scientist and Cuba telecom blogger Larry Press of California State University in Dominguez Hills, is what use the Cuban government has for U.S. telecom equipment.

“In my mind, the question is: What is Cuba going to allow?” he says.

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SpaceX Raises $1 Billion from Google and Fidelity for Satellite Internet Project

SpaceX recently announced plans to provide Internet access through a global network of about 4,000 satellites starting within five years. The private spaceflight company also revealed that it has raised $1 billion in funding from Google and Fidelity to help make those plans a reality.

The mega investment in SpaceX will give Google and Fidelity ownership of about 10 percent of the spaceflight company, according to a SpaceX press release on 20 Jan. A Wall Street Journal report cited a person close to the deal as saying the investment would aid SpaceX’s plans to expand Internet access through its global satellite network:

The investment would value SpaceX, backed by Tesla Motors Inc. Chief Executive Elon Musk, at more than $10 billion, according to a person familiar with the matter. The financing will support the company’s nascent plans to deliver Internet access via satellites, the person said.

The company has already submitted paperwork to international regulators for approval to launch the global satellite network in low-Earth orbit, said Elon Musk, founder and CEO of SpaceX, during an invitation-only announcement on 16 January, according to SpaceNews. Musk also confirmed plans to build a new SpaceX satellite factory in Seattle.

SpaceX’s satellite Internet project dovetails nicely with Google’s ambitions to spread Internet access worldwide through platforms such as balloons, drones, and satellites. Tech giants such as Google and Facebook have been considering a wide array of possible plans for expanding their reach to the world’s untapped market of future Internet users.

SpaceX had previously been in talks with Greg Wyler, a former Google executive and founder of WorldVu Satellites Ltd., about building a joint satellite Internet effort. But the Wall Street Journal says that the talks between SpaceX and Wyler floundered over disagreement about control of the possible joint project. Wyler has apparently gone his own way, leaving SpaceX and Google looking more like allies rather than rivals in the race to spread Internet access.

Musk said that the satellite venture represents a better money-making opportunity for SpaceX compared with its space-launch services. Until now, the spaceflight company has based its business on its fleet of Falcon rockets that launch commercial satellites into orbit and deliver cargo to the International Space Station under a NASA commercial contract.

The potential revenue from the satellite Internet project could help SpaceX move toward Musk’s dream of sending humans to colonize Mars. He made that point very clear during the announcement of the project plans, according to SpaceNews:

This is intended to be a significant amount of revenue and to help fund a city on Mars. Looking at the long term, what’s needed to create a city on Mars? Well, one thing’s for surea lot of money. So we need things that will generate a lot of money.

But any investors excited about getting a piece of the SpaceX future may have to wait until SpaceX is “doing regular flights to Mars” before they can expect an IPO, Musk said. He pointed out that the company’s long-term goals of establishing a human settlement on Mars don’t fit well with the short-term expectations of public shareholders.

High-Resolution Printing of Quantum Dots For Vibrant, Inexpensive Displays

Using a technique much like inkjet printing, engineers have created high-resolution patterns of quantum dots. Quantum dots (QDs) are light-emitting semiconductor nanocrystals that, used in light-emitting diodes (LEDs), hold the promise of brighter, faster displays. But there is no reliable and efficient way to pattern them at a high resolution to create multicolor pixels for displays.

John Rogers, a materials science and engineering professor at the University of Illinois in Urbana-Champaign, and his colleagues are repurposing a printing method they devised for other applications. When used with “QD ink,” it can create lines and spots that are just 0.25 micrometers wide. They made arrays and complex patterns of QDs in multiple colors, and could even print QDs on top of others of a different color. They sandwiched these patterns between electrodes to make bright QD LEDs. Details about the results were published in the journal Nano Letters.

Quantum dot TVs were big at the 2015 Consumer Electronics Show (CES) in Las Vegas. Companies such as Sony, Samsung and LG all have their own version. But the TVs demoed at CES use QDs along with blue inorganic LEDs to create a white backlight. The white light is beamed through color filters at each pixel to generate any color. The quantum dots are simply filled in a tube or painted on the entire backpanel; they don’t need to be patterned.

But companies such as QD Vision and Samsung seek a true QD display, wherein red, green and blue QD LEDs glow at each pixel. QD LED displays would be rich and vibrant thanks to the pure, bright glow of QDs. They would also be efficient and affordable because QDs require very little energy to light up, and they can easily be made into inks and printed.

Seems simple, doesn’t it? It was—except for the fact that no one had been able to print with these inks. The best that researchers had been able to do, Rogers told IEEE Spectrum, was print QDs on a surface using a patterned rubber stamp. But that wouldn’t cut it for mass production.

So Rogers and his team turned to a technique called electrohydrodynamic jet, or e-jet printing, which they developed and used to print patterns of DNA and carbon nanotubes.

The print tool in this case is a metal-coated glass capillary tube with a 5-micrometer nozzle at the end. A pneumatic system pushes the QD ink in the tube just enough that it bulges out of the tip. A voltage bias applied between the capillary and a metallic surface forces free ions in the ink to accumulate in that bulging ink drop.

“As those deposit, they deform the shape of the meniscus from circular to conical,” Rogers explains. “That terminates in the formation of droplets at the tip of the cone.”

The droplets, which are printed on the surface, are much smaller than the nozzle tip because they’re generated from the fluid cone rather than the nozzle itself.

Compared to stamping, he says, “We can do more diverse geometries more easily. There’s an inherent versatility in patterning. And we also eliminate any possible chemical contamination due to contact with the stamp surface.”

The researchers can print QDs on pretty much any surface as long as they lay it on a metal backplane. That means they could print on flexible surfaces, which is an exciting prospect for displays as well as lighting.

The ability to print QDs on top of other QDs, meanwhile, offers a new way to do color mixing. “In a display having separate RGB pixels at each location is one way,” Rogers says. “But you can also imagine mixing red and green by printing on top of one another. You could generate LEDs with any emission color at all by mixing and matching multiple quantum dots.”

Rogers says his team is now working on creating arrays of multiple nozzles, which would be important for manufacturing. Inkjet printers usually have a few hundred nozzles. The difficulty with the e-jet printing method is that the electric field at one nozzle affects the fields of neighboring nozzles. So the engineers are trying to figure out how to isolate nozzles in order to eliminate that crosstalk.

Privately-funded Solar Sail Prepared For Launch

In a parallel universe, a NASA-sponsored experimental solar sail—the largest ever built—would be launching into space next month along with the solar wind-monitoring DSCOVR spacecraft. That won’t happen in this universe: NASA cancelled the Sunjammer launch last year due to scheduling concerns, and it’s not clear when, or even if, the sail will get another opportunity to fly.

But there is a bright spot on the near horizon for solar sail tests. The space advocacy organization The Planetary Society today announced that a date has been set for the first flight of its LightSail spacecraft. The 30-centimeter-long CubeSatan increasingly popular class of small spacecraftis set to take off from Cape Canaveral Air Force Station in May as a secondary payload on an Atlas V rocket.

Solar sails are propelled by the momentum that photons impart when they bounce off a reflective surface. This method of propulsion can provide slow but steady acceleration to high speeds, which could cut down on the cost and mass of interplanetary missions. With the assistance of a powerful laser beam, the same technique might be used to propel spacecraft to interstellar mission speeds.

Solar sails “will ultimately eventually take a lot of missions a long, long way,” Planetary Society CEO Bill Nye told the New York Times. He said that this spacecraft—and a second one set to launch next year—together cost less than US $4 million to build. 

This first LightSail, integrated and tested by the Pasadena, Calif.–based Ecliptic Enterprises, will spend a month or so in orbit before it unfurls Mylar sheets along 4-meter-long booms to create a 32-square-meter sail. The first flight will be a shakedown mission to test sail deployment and other aspects of the spacecraft. But the sailing will have to wait; the spacecraft will be carried to a fairly low orbit where it will experience significant drag from the atmosphere. The second spacecraft, slated to launch in 2016 on a SpaceX Falcon Heavy rocket, will reach a higher orbit where solar pressure can be used to maneuver.

Other spacecraft have used radiation pressure to adjust their orbits, and solar sails have already had a few successful missions. In 2010, the Japan’s space agency JAXA launched a solar sail called IKAROS (short for Interplanetary Kite-craft Accelerated by Radiation Of the Sun) on a mission past Venus. And in 2011, NASA successfully unfurled NanoSail-D, also a compact CubeSat, in low-Earth orbit.

The new Planetary Society mission comes some 10 years after its first solar sail spacecraft, Cosmos 1, fell to Earth after a rocket failure. 

The Planetary Society's Jason Davis writes that the team has been sharing data with NASA teams that are working on additional solar-sail-bearing CubeSat missions. The space agency aims to launch at least two such missions (not all payloads have been selected yet) on the maiden voyage of the new heavy-lift Space Launch System, which could happen as early as 2018. One of the spacecraft, Lunar Flashlight, will use its solar sail to maneuver and to reflect light onto the moon's south pole.

Entanglement On a Chip

Quantum entanglement is a phenomenon where particles act in sync, even if they are at separate ends of the universe. Links of this type are so delicate that, if anyone tried to eavesdrop on a message sent using a stream of entangled particles, the disturbance would immediately be obvious. This has led to extraordinarily secure quantum cryptography that can instantly detect any spying.

But if this phenomenon is to be used to keep cellphone conversations private or make sure that no one can sniff out your banking password, scientists have to first generate entangled photons using electronics that can fit onto a microchip. However, until now, entangled photon emitters could only be scaled down to millimeters in size, too large for on-chip applications by several orders of magnitude. In addition, such emitters required much more power than is practical for putting them on, say, a cellular handset.

Now researchers at the University of Pavia in Italy say they have developed a device that can generate a continuous supply of entangled photons and is small enough to fit on a microchip. The scientists detailed their findings on 26 January in the online edition of the journal Optica.

The key component of the device is a "micro-ring resonator," a 20-micrometer-diameter ring etched into a silicon wafer. The ring is 500 nanometers wide and 220 nanometers high. When a laser beam is directed along an optical fiber and into the device, the photons race around the ring and can become entangled. “The key to this result is the ability to confine light and matter in the same microscopic place for as long as possible to force their interaction,” Daniele Bajoni, a physicist at the University of Pavia in Italy who is a member of the research team, told IEEE Spectrum.

The device can generate 10 million entangled pairs of photons per second, and requires less than a milliwatt of power—thousands of times less than was needed by previous entangled photon emitters. The researchers employ lasers with a wavelength of 1,550 nanometers, which is often used in telecommunications. They suggest their device could be readily incorporated into existing silicon chip technologies.

Bajoni and his colleagues now aim to integrate this device onto microchips. “I would like to caution the lay reader that we are not going to see a quantum version of the Internet, in which you can send quantum-encrypted e-mails, anytime soon,” Bajoni said. “It is probable that the first applications will be point-to-point exchanges of information. For instance, one can think of quantum ATM machines where bank clients can exchange quantum cryptography keys to be used for home banking.”


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