Nice forum on QC Crystal Superconduction in Mar.
From March 8–10, 2017, an International Conference on Crystal Growth is to be held in Freiburg under the auspices of the German Association of Crystal Growth DGKK and the Swiss Society for Crystallography SGK-SSCR. The conference, jointly organized by the Fraunhofer Institute for Solar Energy Systems ISE, the Crystallography department of the Institute of Earth and Environmental Sciences at the University Freiburg and the University of Geneva, is to be held in the seminar rooms of the Chemistry Faculty of the University of Freiburg. Furthermore, the Young DGKK will hold a seminar for young scientists at Fraunhofer ISE on March 7, 2017.
“Whether for mobile communication, computers or LEDs, crystalline materials are key components of our modern lifestyle,” says Dr. Stephan Riepe, group head in the Department of Silicon Materials at Fraunhofer ISE. “Crystal growth has a long tradition and today is still far from becoming obsolete. Materials with special crystalline structure are being developed for applications in high-temperature superconductors through to low-loss power transmission. Artificial diamonds are a favorite choice for building quantum computers. At the conference, the production of silicon, III-V semiconductors and most currently perovskite layers for cost-effective high efficiency tandem solar cells will also be discussed.”
In Freiburg, a close cooperation exists between the Fraunhofer Institutes and the University of Freiburg. For example, at Fraunhofer ISE a doctoral thesis of the University of Freiburg was carried out which investigated how impurities can be minimized during multicrystalline silicon production. In the production process, liquid silicon is melted in a quartz crucible and subsequently solidified. Similar to flour’s function when sprinkled in a baking form, silicon nitride powder acts as a separating agent between the crucible and the silicon. Here the aim is to reduce impurities on the scale of parts per billion, or ppb, to achieve the highest solar cell efficiencies. On a regular basis, student and doctoral degree theses are carried out to address such questions.
Add RadioBio/ Quantum Biosystem technology and this will be perfect.
Soft robotics researchers at the University of Wollogong (UOW) in Australia have used 3D printing to build a realistic robotic hand that can be controlled by brain signals and which has a surface texture similar to human skin.
Dr Rahim Mutlu (left), Professor Gursel Alici, and their 3D printed hand collection
At the U.S. Army’s annual Maneuver and Fires Integration Experiment (MFIX), the Blitzer railgun performed successfully during eleven test firings. The test projectiles contained a Guidance Electronics Unit (GEU), which beamed back telemetry indicating the shells achieved an acceleration of over 30,000 gravities, and that all components survived the multi-Tesla magnetic field that powers the launcher.
“We continue to perform risk reduction and technology maturation of projectile designs and components to culminate in an integrated demonstration of a maneuvering railgun launched projectile,” says Nick Bucci, vice president of Missile Defense and Space Systems at General Atomics Electromagnetic Systems.
The next step is to integrate the system into a mobile, truck-based platform.
Nice.
Physicists at the University of Bonn have cleared a further hurdle on the path to creating quantum computers: in a recent study, they present a method with which they can very quickly and precisely sort large numbers of atoms. The work has now been published in Physical Review Letters.
Imagine you are standing in a grocery store buying apple juice. Unfortunately, all of the crates are half empty because other customers have removed individual bottles at random. So you carefully fill your crate bottle by bottle. But wait: The neighboring crate is filled in exactly the opposite way! It has bottles where your crate has gaps. If you could lift these bottles in one hit and place them in your crate, it would be full straight away. You could save yourself a lot of work.
Unfortunately, such solutions don’t (yet) exist for half-empty drinks crates. However, physicists at the University of Bonn want to sort thousands of atoms however they like in the future in this way — and in a matter of seconds. Around the world, scientists are currently looking for methods that enable sorting processes in the microcosm. The proposal by Bonn-based researchers could push the development of future quantum computers a crucial step forward. This allows atoms to interact with each other in a targeted manner in order to be able to exploit quantum-mechanical effects for calculations. In addition, the particles have to be brought into spatial proximity with one another.
New Graphene based flash memory card coming.
Dotz Nano (ASX: DTZ) has successfully completed a proof of concept research study into the use of Graphene Quantum Dots (GQDs) in flash memory devices with the Kyung Hee University in South Korea.
GQDs are being developed for use in various applications including medical imaging, sensing, consumer electronics, energy storage, solar cells and computer storage.
Dotz Nano is in advanced negotiations to sign a full licensing agreement with Kyung Hee University related to this technology.
I don’t know how to say this; however, Apple has already shared their own experiment Li-Fi over a year ago; now this from IEEE.
Now an advance by a team of researchers from the University of Illinois at Urbana–Champaign, the Electronics and Telecommunications Research Institute in South Korea and Dow Chemical may turn the display market on its head by eliminating the need for backlights in LCD devices. They have produced a LED pixel out of nanorods capable of both emitting and detecting light.
In the video below, you can get a further description of how the nanorods manage to both detect and emit light as well as some pretty attractive future applications, like mobile phones that can “see” without the need of a camera lens or communicate with each other using Light Fidelity (Li-Fi) technology.
Over the past week, the White House appointed five new senior National Security Council staff officials. Two in particular signify the emerging and disruptive influence Billionaire tech investor Peter Thiel could have on U.S. national security and how he might bring his venture capital perspective — visionary but unconventional leaders, big bets on disrupting established industries — to national security.
Kevin Harrington, a Thiel acolyte, has been named Deputy Assistant to the President for strategic planning. Since early December, Harrington served on the Trump “landing team” at the Commerce Department, where his job was to help hire people for open positions and identify policy priorities. Before that, he worked at hedge funds started by Thiel. Michael Anton, a former executive at an investment management firm and speechwriter, was named Deputy Assistant to the President for Strategic Communications, virtually the same job that Obama advisor Ben Rhodes held. POLITICO reports that he received the position “thanks to an entree from Thiel.”
The Harrington appointment is unusual for a couple of reasons. First, the elevation of this position to “Deputy Assistant to the President,” the second highest rank within the White House, suggests that Harrington will have a larger role than his predecessors. Although the strategic planning office is one of the most important at the NSC, it is typically staffed by a lean team of forward thinkers and the head of the office is ranked accordingly.
Well, I asked about Apple’s own investment in QC; we now have our answer.
Today the US Patent & Trademark Office published a patent application from Apple that reveals a new breakthrough material described as deformable touch-sensitive quantum tunneling material. It could be used in a smart iPhone case allowing for touch zones on the back of the case to control your iPhone. More importantly, it could be used as a material for making the iPhone itself. The use of this material would virtually eliminate bulky physical buttons forever making the iPhone near waterproof perfect and slick to the touch. The material could extend to a new smart Apple Watch band. Smart Apple Watch Bands have been on Apple’s mind for some time now as we’ve covered a number of interesting patent ideas like smart links, chameleonic bands with 3D touch and cooling and, easy recharging with a MacBook. Yet the use of quantum tunneling material in a band would allow for touch controls without seeing any buttons.
This could also apply to accessories like future EarPods to eliminate the bulky remote and much more. This breakthrough material will eventually provide Jony Ive’s industrial design team with new ways to streamline designs and finally eliminate physical buttons of any kind while allowing device designs to be even thinner.
There’s been more exciting patents revealed today than I’ve seen in some time. Seeing a new wave of Apple innovations is exactly what the doctor ordered to fire up fans. While it may take some time for this to come to market, the promise of cool next generation designs is guaranteed.
