The important thing is that observation ruins the entanglement. So it’s only a tip for understanding the way the quantum universe works, and therefore the way forces interact; it’s NOT useful for faster-than-light communication or, at least as I understand it, quantum computing.
Of course, when I say it’s not useful for faster-than-light communication, I refuse to disallow the possibility that it might just help us find a loophole in the laws of physics that would allow such communication.
Spoilsport. :D
Not useful for quantum computing?
They're well on their way to doing just that. Don't have much time at the moment to look up some stuff on it, but please feel free to do it yourself.
I'll see what I can do in what little time I have left...
Perhaps they can somehow use the instantaneous "spooky action at a distance" (over arbitrarily long distances) quantum (now macro?) phenomenon to 'flip a switch' of sorts as a means of simple, but potentially powerful, communication.
A multinational team of researchers led by University of Cambridge scientist Dr. Alessandro Rossi and University of Adelaides Dr. Giuseppe Tettamanzi has developed a ground-breaking single-electron pump. Their work was published on June 19, 2018 in the journal Nano Letters.
In quantum metrology, semiconductor single-electron pumps are used to generate accurate electric currents with the goal of implementing the emerging quantum standard of the ampere, said Dr. Rossi, Dr. Tettamanzi and their colleagues from Aalto University and the Universities of New South Wales and Latvia.
Pumps based on electrostatically defined tunable quantum dots have thus far shown the most promising performance in combining fast and accurate charge transfer.
However, at frequencies exceeding approximately 1 GHz the accuracy typically decreases.
The single-electron pump developed by the team can produce one billion electrons per second and uses quantum mechanics to control them one-by-one.
Its so precise the scientists have been able to use their device to measure the limitations of current electronics equipment.
Achieving full control of electrons in these nano-systems will be highly beneficial for realistic implementation of a scalable quantum computer, Dr. Tettamanzi said.
We, of course, have been controlling electrons for the past 150 years, ever since electricity was discovered. But, at this small scale, the old physics rules can be thrown out.
In the Nano Letters paper, the scientists also report observations of electron behavior thats never been seen before a key finding for those around the world working on quantum computing.
Quantum computing, or more broadly quantum information processing, will allow us to solve problems that just wont be possible under classical computing systems, Dr. Tettamanzi said.
It operates at a scale thats close to an atom and, at this scale, normal physics goes out the window and quantum mechanics comes into play.
To indicate its potential computational power, conventional computing works on instructions and data written in a series of 1s and 0s think about it as a series of on and off switches; in quantum computing every possible value between 0 and 1 is available.
We can then increase exponentially the number of calculations that can be done simultaneously.
This research puts us one step closer to the holy grail reliable, high-performance quantum computing, he said.
http://www.sci-news.com/physics/single-electron-pump-06195.html