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May 9, 2016

Artificial Intelligence Evolution: Future AI Technologies To Make AI Obsolete And Intertwine Physical, Digital Realities?

Posted by in categories: evolution, robotics/AI, singularity

The troubling piece of this article is that the article leaves out how the underlying technology will need to change in order for AI to truly intertwine with humans. AI in the existing infrastructure and digital technology with no support of BMI, microbots, etc. will not evolve us to Singularity by itself and without changes to the existing digital landscape.


As artificial intelligence continuously evolves, the future of AI is also becoming more significantly challenging to perceive and comprehend for humans.

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May 9, 2016

How Quantum Entanglement Can Help You Understand Many-Worlds

Posted by in categories: materials, quantum physics

Quantum Entanglement by Orzel part 2.


Entanglement is weird, but also provides a nice, concrete experimental framework that can ground an explanation of how decoherence hides the existence of other branches of the wavefunction.

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May 9, 2016

Samsung’s Quantum Dot TV Tech to Find Medical Applications

Posted by in categories: bioengineering, chemistry, electronics, food, nanotechnology, quantum physics

Samsung get into the cancer treatment space with their own Q-Dot technology? Another reason for the FDA to show up in tech’s backyard; lookout for all those future federal and state regs & compliance training that will be coming that eats up 20 hours each month of your scientists and engineering talent’s time.


For a lot of users, Samsung might be known best for their smartphones and other mobile devices, but the company is so much more than that. Many of you reading this might have one of Samsung’s Super HD TV sets, a curved Samsung TV or some other model of theirs. Next to smartphones one of their more popular consumer electronics is of course of TVs, and with the advent of new technology such as Quantum Dot, Samsung is getting even better at producing a great image. One area that you might expect to find this Quantum Dot technology being used is for medical uses, but that’s just what researchers have been exploring recently.

Explaining a Quantum Dot can become quite tricky, but to cut a long story short, they are semiconductors that are so small they register at the nanoscale side of things. In terms of Quantum Dots used in television displays, it’s their ability to precisely tune to a specific and exact part of the color spectrum that makes them so attractive, not to mention their much lower power draw. Now, Kim Sung-jee, a professor of the Chemistry department at Pohang University of Science and Technology (POSTECH), has said that “when combining protein which clings to cancer cells and quantum dots, it can be used to seek out cancer cells in the body”. It’s reasoned that the potential for these Quantum Dots to be so precise in terms of color reproduction can help physicians track down certain cancer cells.

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May 9, 2016

First single-enzyme method to produce quantum dots revealed

Posted by in categories: engineering, particle physics, quantum physics, solar power, sustainability

Creating Q-Dots/ QDs (Acronym seems to depend on which reference book, article that you read) more cheaply and efficiently too.


Quantum dots (QDs) are semiconducting nanocrystals prized for their optical and electronic properties. The brilliant, pure colors produced by QDs when stimulated with ultraviolet light are ideal for use in flat screen displays, medical imaging devices, solar panels and LEDs. One obstacle to mass production and widespread use of these wonder particles is the difficulty and expense associated with current chemical manufacturing methods that often requiring heat, high pressure and toxic solvents.

But now three Lehigh University engineers have successfully demonstrated the first precisely controlled, biological way to manufacture quantum dots using a single-enzyme, paving the way for a significantly quicker, cheaper and greener production method. Their work was recently featured in an article in The New York Times called “A curious tale of quantum dots.”

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May 9, 2016

The Quantum Experience: Feynman’s vision comes into focus

Posted by in categories: computing, quantum physics

Great article about a mad-scientist whose vision caused the world to look cross-eyed. Many of us have been there before some time in our lives.

In 1981, Richard Feynman urged the world to build a quantum computer. In his own words.

“Nature isn’t classical, dammit, and if you want to make a simulation of nature, you’d better make it quantum mechanical, and by golly it’s a wonderful problem, because it doesn’t look so easy.”

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May 9, 2016

Communicating covertly goes quantum

Posted by in category: quantum physics

Communication Quantum Style!

https://www.sciencenews.org/article/communicating-covertly-goes-quantum


Researchers are working to make quantum messages that are undetectable.

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May 9, 2016

A.I. Is Getting Better at Spotting Galaxies

Posted by in categories: computing, robotics/AI, space

It would take human volunteers 120,000 years to classify every galactic image that comes through a new space telescope. That’s where computers come in.

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May 9, 2016

Researchers Making Progress With Quantum Computing

Posted by in categories: computing, governance, government, internet, particle physics, quantum physics

I personally can confirm that QC is not being worked on and advance by just a couple groups such as D-Wave and IBM. The questions/bumps in the road that we will all face is threefold:

1) how do we standardize the QC? right now (like most innovation) is done in siloes and limited cross-collaboration across government, labs & universities, and commercial companies. 2) governance and compliance; how will these need to change across multiple areas 3) id & mitigate all impacts instead of after deployment (don’t be reactive) because we will not have that luxury due to hackers.


There is a temptation to lump quantum computing in with technologies such as fusion power in the sense that both have been proposed for decades with the promise of tremendous leaps in performance.

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May 9, 2016

Neutrons tap into magnetism in topological insulators at high temperatures

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

I know that I reported on this a few weeks ago; however, this article shares some additional insights on how this new method will enable more efficient smaller devices including promoting stabilization in Quantum Computing (QC)…


A multi-institutional team of researchers has discovered novel magnetic behavior on the surface of a specialized material that holds promise for smaller, more efficient devices and other advanced technology.

Researchers at the Department of Energy’s Oak Ridge National Laboratory, Massachusetts Institute of Technology and their collaborators used neutron scattering to reveal magnetic moments in hybrid topological insulator (TI) materials at room temperature, hundreds of degrees Fahrenheit warmer than the extreme sub-zero cold where the properties are expected to occur.

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May 9, 2016

Quantum Swing: a pendulum that moves forward and backwards at the same time

Posted by in categories: particle physics, quantum physics

One of those freaky states of Quantum. Wild.


Two-quantum oscillations of atoms in a semiconductor crystal are excited by ultrashort terahertz pulses. The terahertz waves radiated from the moving atoms are analyzed by a novel time-resolving method and demonstrate the non-classical character of large-amplitude atomic motions.

The classical pendulum of a clock swings forth and back with a well-defined elongation and velocity at any instant in time. During this motion, the total energy is constant and depends on the initial elongation which can be chosen arbitrarily. Oscillators in the quantum world of atoms and molecules behave quite differently: their energy has discrete values corresponding to different quantum states. The location of the atom in a single quantum state of the oscillator is described by a time-independent wavefunction, meaning that there are no oscillations.

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