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Aug 8, 2016

DARPA wants to build very low frequency wireless systems

Posted by in category: futurism

Well, we can easily figure out who this and how this will be used on.


Wireless transmitters that operate at very or ultra low frequencies (0.3‐30 kHz) typically require some big antenna complexes to handle their communications.

Scientists at the Defense Advanced Research Projects Agency (DARPA) said they are interested looking to eliminate that issue and develop smaller physical structures that could handle new long-distance communication applications.

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Aug 8, 2016

Artificial Intelligence Just Changed the Future of Information Security – Defense One

Posted by in categories: computing, quantum physics, robotics/AI, security

I will like to see how this stacks against China’s Quantum net, QC platform, AI, and hackers in the future. Not sold at this point until we truly have a QC infrastructure in place.


At DARPA’s Cyber Grand Challenge, bots showed off their ability to help a world wallowing in vulnerable code.

LAS VEGAS, Nev. — Mayhem ruled the day when seven AIs clashed here last week — a bot named Mayhem that, along with its competitors, proved that machines can now quickly find many types of security vulnerabilities hiding in vast amounts of code.

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Aug 8, 2016

Futurism Photo

Posted by in categories: augmented reality, biotech/medical, virtual reality

“You can take any anatomical part and show any of it. You can move it around you can make it kind of translucent so you can see through the outside”

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Aug 8, 2016

Diamond-based light sources will lay a foundation for quantum communications of the future

Posted by in categories: computing, nanotechnology, particle physics, quantum physics

Dmitry Fedyanin from the Moscow Institute of Physics and Technology and Mario Agio from the University of Siegen and LENS have predicted that artificial defects in the crystal lattice of diamond can be turned into ultrabright and extremely efficient electrically driven quantum emitters. Their work, published in New Journal of Physics, demonstrates the potential for a number of technological breakthroughs, including the development of quantum computers and secure communication lines that operate at room temperature.

The research conducted by Dmitry Fedyanin and Mario Agio is focused on the development of electrically driven single-photon sources—devices that emit when an electrical current is applied. In other words, using such devices, one can generate a photon “on demand” by simply applying a small voltage across the devices. The probability of an output of zero photons is vanishingly low and generation of two or more photons simultaneously is fundamentally impossible.

Until recently, it was thought that quantum dots (nanoscale semiconductor particles) are the most promising candidates for true single-photon sources. However, they operate only at very low temperatures, which is their main drawback – mass application would not be possible if a device has to be cooled with liquid nitrogen or even colder liquid helium, or using refrigeration units, which are even more expensive and power-hungry. At the same time, certain point defects in the crystal lattice of diamond, which occur when foreign atoms (such as silicon or nitrogen) enter the diamond accidentally or through targeted implantation, can efficiently emit single photons at room temperature. However, this has only been achieved by optical excitation of these defects using external high-power lasers. This method is ideal for research in scientific laboratories, but it is very inefficient in practical devices.

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Aug 8, 2016

Toward practical quantum computers: Built-in optics could enable chips that use trapped ions as quantum bits

Posted by in categories: computing, quantum physics

Quantum computers are largely hypothetical devices that could perform some calculations much more rapidly than conventional computers can. Instead of the bits of classical computation, which can represent 0 or 1, quantum computers consist of quantum bits, or qubits, which can, in some sense, represent 0 and 1 simultaneously.

Although quantum systems with as many as 12 have been demonstrated in the lab, building quantum computers complex enough to perform useful computations will require miniaturizing qubit technology, much the way the miniaturization of transistors enabled modern computers.

Trapped ions are probably the most widely studied qubit technology, but they’ve historically required a large and complex hardware apparatus. In today’s Nature Nanotechnology, researchers from MIT and MIT Lincoln Laboratory report an important step toward practical quantum computers, with a paper describing a prototype chip that can trap ions in an electric field and, with built-in optics, direct toward each of them.

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Aug 8, 2016

Researchers Made the First Quantum Enigma Machine

Posted by in categories: encryption, quantum physics

A quantum enigma machine is theoretical device that is able to use photons to encrypt messages using keys that are shorter than the message itself—and now it’s real.

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Aug 8, 2016

Interesting Futurism Photo 2

Posted by in category: futurism

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Aug 8, 2016

Researchers Receive NSF Grant to Develop New Quantum Technologies for Secure Communication

Posted by in category: quantum physics

August 08, 2016 | By Liezel Labios Researchers Receive NSF Grant to Develop New Quantum Technologies for Secure Communication.

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Aug 8, 2016

Scientists Create Language to Program Living Cells

Posted by in categories: biotech/medical, computing, education, internet

Nice — another step forward for all things connected.


Scientists can now talk to and even command living cells–to a limited degree at the moment, but with massive implications for the future. MIT biological engineers have created a computer code that allows them to basically hijack living cells and control them. It works similarly to a translation service, using a programming language to create a function for a cell in the form of a DNA sequence. Once it’s scalable, the invention has major ramifications. Future applications could include designing cells that produce a cancer drug when a tumor is detected or creating yeast cells that halt their own fermentation if too many toxic byproducts build up.

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Aug 8, 2016

China may be the future of genetic enhancement

Posted by in categories: bioengineering, biotech/medical, economics, genetics, neuroscience

Indeed, if we set ethical and safety objections aside, genetic enhancement has the potential to bring about significant national advantages. Even marginal increases in intelligence via gene editing could have significant effects on a nation’s economic growth. Certain genes could give some athletes an edge in intense international competitions. Other genes may have an effect on violent tendencies, suggesting genetic engineering could reduce crime rates.


We may soon be able to edit people’s DNA to cure diseases like cancer, but will this lead to designer babies? If so, bioethicist G Owen Schaefer argues that China will lead the way.

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