Archive for the ‘quantum physics’ category: Page 762
Aug 6, 2016
New Form Of Light Could Make Study Of Quantum Phenomena Easier
Posted by Karen Hurst in categories: materials, quantum physics
In a development that could greatly help the study of quantum phenomena, scientists have created a theoretical model for a new form of light that combines the properties of photons and electrons. If turned into reality, the new light form could also be used to make electrical circuits which at present use electrons for conduction.
Scientists from Imperial College London published a study in the journal Nature Communications on Friday that shows “it is possible to create a new form of light by binding light to a single electron, combining the properties of both,” according to a statement issued by the college.
Light, which is made up of photons, usually interacts with a large number of electrons on the surface of whatever material it comes in contact with. For the study, researchers from Imperial used “a recently discovered class of materials known as topological inhibitors.” Combining that with “theoretical physics to model the behavior of light,” they found that light could interact with only one electron on the surface.
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Aug 6, 2016
USC quantum computing researchers reduce quantum information processing errors
Posted by Karen Hurst in categories: computing, information science, quantum physics, robotics/AI
Quantum computing remains mysterious and elusive to many, but USC Viterbi School of Engineering researchers might have taken us one step closer to bring such super-powered devices to practical reality. The USC Viterbi School of Engineering and Information Sciences Institute is home to the USC-Lockheed Martin Quantum Computing Center (QCC), a super-cooled, magnetically shielded facility specially built to house the first commercially available quantum optimization processors — devices so advanced that there are currently only two in use outside the Canadian company D-Wave Systems Inc., where they were built: The first one went to USC and Lockheed Martin, and the second to NASA and Google.
Quantum computers encode data in quantum bits, or “qubits,” which have the capability of representing the two digits of one and zero at the same time — as opposed to traditional bits, which can encode distinctly either a one or a zero. This property, called superposition, along with the ability of quantum states to “interfere” (cancel or reinforce each other like waves in a pond) and “tunnel” through energy barriers, is what may one day allow quantum processors to ultimately perform optimization calculations much faster than is possible using traditional processors. Optimization problems can take many forms, and quantum processors have been theorized to be useful for a variety of machine learning and big data problems like stock portfolio optimization, image recognition and classification, and detecting anomalies. Yet, exactly because of the exotic way in which quantum computers process information, they are highly sensitive to errors of different kinds.
Aug 4, 2016
Hackers could get inside your brain, warns experts
Posted by Karen Hurst in categories: cybercrime/malcode, neuroscience, quantum physics
I have reported on this threat for a very long time as we see more BMI technology advance. However, one are where things could drastically reduce hacking and breeches is the migration to a Quantum based net and infrastructure.
Cyberthieves might be mining personal information from your brainwaves at this very moment.
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Aug 4, 2016
New way to model molecules
Posted by Karen Hurst in categories: biological, chemistry, computing, encryption, quantum physics, robotics/AI, solar power, sustainability
Magine a future in which hyper-efficient solar panels provide renewable sources of energy, improved water filters quickly remove toxins from drinking water, and the air is scrubbed clean of pollution and greenhouse gases. That could become a reality with the right molecules and materials.
Scientists from Harvard and Google have taken a major step toward making the search for those molecules easier, demonstrating for the first time that a quantum computer could be used to model the electron interactions in a complex molecule. The work is described in a new paper published in the journal Physical Review X by Professor Alán Aspuru-Guzik from the Department of Chemistry and Chemical Biology and several co-authors.
“There are a number of applications that a quantum computer would be useful for: cryptography, machine learning, and certain number-theory problems,” Aspuru-Guzik said. “But one that has always been mentioned, even from the first conceptions of a quantum computer, was to use it to simulate matter. In this case, we use it to simulate chemistry.”
Aug 4, 2016
Watch opera and quantum computing collide in ‘Superposition’: the most high-tech duet ever
Posted by Karen Hurst in categories: computing, quantum physics
Wonder if they’ll come to the Met in NY, or the Hollywood Bowl in CA.
A Welsh mezzo-soprano in England recently performed a real-time duet with a quantum computer. Here’s how it sounded.
Aug 4, 2016
Google Quantum Computing Breakthrough
Posted by Andreas Matt in categories: computing, quantum physics
Aug 3, 2016
Programmable ions set the stage for general-purpose quantum computers
Posted by Andreas Matt in categories: computing, information science, particle physics, quantum physics
Quantum computers promise speedy solutions to some difficult problems, but building large-scale, general-purpose quantum devices is a problem fraught with technical challenges.
To date, many research groups have created small but functional quantum computers. By combining a handful of atoms, electrons or superconducting junctions, researchers now regularly demonstrate quantum effects and run simple quantum algorithms —small programs dedicated to solving particular problems.
But these laboratory devices are often hard-wired to run one program or limited to fixed patterns of interactions between the quantum constituents. Making a quantum computer that can run arbitrary algorithms requires the right kind of physical system and a suite of programming tools. Atomic ions, confined by fields from nearby electrodes, are among the most promising platforms for meeting these needs.
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Aug 3, 2016
Quantum Computing Just Grew Way the Hell Up
Posted by Karen Hurst in categories: computing, information science, quantum physics
Additional insights on the latest reprogrammable QC.
Researchers implement a key piece of Shor’s algorithm in a programmable quantum computer.
Aug 3, 2016
China to launch unbreakable quantum spy satellite
Posted by Karen Hurst in categories: quantum physics, space
Exciting news today about the new smaller reprogrammable QC discovery; however, in China.
Scientists in China are set to launch the world’s first ‘quantum satellite,’ which could one day make for an ultra-secure global communications network.
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