Quantum Test Could Reveal Limits of our Mind

The boundary between mind and matter could be tested using a new twist on a well-known experiment in quantum physics. Over the past two decades, a type of experiment known as a Bell test has confirmed the weirdness of quantum mechanics – specifically the 'spooky action at a distance' that so bothered Einstein. Now, a theorist proposes a Bell test experiment using something unprecedented: human consciousness. If such an experiment showed deviations from quantum mechanics, it could provide the first hints that our minds are potentially immaterial. Spooky action at a distance was Einstein’s phrase for a quantum effect called entanglement. If two particles are entangled, then measuring the state of one particle seems to instantly influence the state of the other, even if they are light years apart. But any signal passing between them would have to travel faster than the speed of light, breaking the cosmic speed limit. To Einstein, this implied that quantum theory was incomplete, and that there was a deeper theory that could explain the particles’ behaviour without resorting to weird instantaneous influence.

Nowadays, researchers proposed an experiment in which A and B are set 100 kilometres apart. At each end, about 100 humans are hooked up to EEG headsets that can read their brain activity. These signals are then used to switch the settings on the measuring device at each location. The idea is to perform an extremely large number of measurements at A and B and extract the small fraction in which the EEG signals caused changes to the settings at A and B after the particles departed their original position but before they arrived and were measured. If the amount of correlation between these measurements doesn’t tally with previous Bell tests, it implies a violation of quantum theory, hinting that the measurements at A and B are being controlled by processes outside the purview of standard physics. Such a finding would stir up debate about the existence of free will. It could be that even if physics dictated the material world, the human mind not being made of that same matter would mean that we could overcome physics with free will.

More information:

https://www.newscientist.com/article/2131874-a-classic-quantum-test-could-reveal-the-limits-of-the-human-mind/

Quantum Boost for AI

Quantum computers of the future will have the potential to give artificial intelligence a major boost, a series of studies suggests. These computers, which encode information in 'fuzzy' quantum states that can be zero and one simultaneously, have the ability to someday solve problems, such as breaking encryption keys, that are beyond the reach of ‘classical’ computers. Algorithms developed so far for quantum computers have typically focused on problems such as breaking encryption keys or searching a list — tasks that normally require speed but not a lot of intelligence.

 

Researchers of the Massachusetts Institute of Technology in Cambridge have put a quantum twist on artificial intelligence. They developed a quantum version of 'machine learning', a type of artificial intelligence in which programs can learn from previous experience to become progressively better at finding patterns in data. Machine learning is popular in applications ranging from e-mail spam filters to online-shopping suggestions. The team’s invention would take advantage of quantum computations to speed up machine-learning tasks exponentially.

More information:

http://www.nature.com/news/quantum-boost-for-artificial-intelligence-1.13453

Quantum Algorithm Breakthrough

An international research group led by scientists from the University of Bristol, UK, and the University of Queensland, Australia, has demonstrated a quantum algorithm that performs a true calculation for the first time. Quantum algorithms could one day enable the design of new materials, pharmaceuticals or clean energy devices.

The team implemented the ‘phase estimation algorithm’ — a central quantum algorithm which achieves an exponential speedup over all classical algorithms.  It lies at the heart of quantum computing and is a key sub-routine of many other important quantum algorithms, such as Shor’s factoring algorithm and quantum simulations.

More information:

http://www.bris.ac.uk/news/2013/9172.html