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Chinese Physicists Measure Speed of “Spooky Action At a Distance”

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March 7, 2013

Einstein railed against the possibility of spooky action at a distance because it violates relativity. Now Chinese physicists have clocked it travelling more than four orders of magnitude faster than light

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One of the strangest concepts in quantum mechanics is the notion of entanglement. This is the idea that two quantum particles can be so deeply linked that they share the same existence. When that happens, a measurement on one immediately influences the other, regardless of the distance between them.

This “spooky action at a distance”, as Einstein called it, has puzzled and fascinated physicists since it was first discussed in the 1930s. Einstein initially used it as evidence of the failure of quantum mechanics since this instantaneous action clearly seemed to violate relativity.

Later, physicists realised there was no conflict because the “spooky action” cannot be used to send information faster than the speed of light. However, important questions remain about the nature of entanglement and spooky action. “If the spooky action does exist, what is its speed?” ask Juan Yin and pals at the University of Science and Technology of China in Shanghai.

Today, they reveal the answer. They say spooky action travels at least four orders of magnitude faster than light.

Measuring the speed of spooky action is no trivial task. The method is to create a pair of entangled particle photons and separate them by a significant distance, in this case 15 km or so. The experiment involves performing a measurement on one photon and then timing how long it takes for the other photon to be influenced.

Of course, this is tricky to do with a single pair of photons because of the tiny periods of time involved and the rotation of the Earth which moves the experiment by distances that are significant over these time scales.

So the trick is to create a stream of entangled photons and to measure the spooky action continuously for 12 hours or more. If the experiment is aligned in an East-West direction, the contribution from the Earth’s rotation should drop out over that time.

Juan and co have perfected this technique by sending photons through the atmosphere from a fish farm near Qinghai Lake in the Tibetan Plateau. (We looked at their work last year when the same team smashed the distance record for teleporting photons using similar gear.)

They say the results are clear but do not measure the speed of spooky action directly. Instead, the results place a lower bound on how fast it must be. The answer is that it is at least four orders of magnitude faster than light, and may still turn out to be instantaneous, as quantum mechanics predicts.

If this result sounds familiar, it’s because a European team based at the University of Geneva in Switzerland carried out a similar experiment in 2008 getting a similar result. However, this turned out to contain a loophole which allowed the results to be explained without entanglement. “All previous experiments along this direction have locality loopholes and thus can be explained without having to invoke any `spooky action’ at all,” say Juan and co.

Now the Chinese team claim to have closed this loophole and say theirs is the first legitimate measurement of the speed of spooky action. It’ll be interesting to see whether they can raise this bound in future and find out how fast they can go.

Chinese Physicists Measure Speed of "Spooky Action At a Distance" | MIT Technology Review

Posted: Mar 8th, 2013

China to Launch Quantum Experiment Satellite in 2016

China has initiated to launch a satellite for quantum information and technology experiments in 2016, a leading quantum physicist said in Beijing on Thursday.

Prof. Pan Jianwei said, "We hope to establish a quantum communication network from Beijing to Vienna."

"Such a plan is impossible without international collaborations," Pan said at a press conference on the sidelines of the annual session of the Chinese People's Political Consultative Conference, China's top political advisory body.

The field of quantum communication, the science of transmitting quantum states from one place to another, has caught global attention in recent years owing to the discovery of quantum cryptography, which is described as a way of creating "unbreakable" messages.

A member of the Chinese Academy of Sciences, Prof. Pan of the University of Science and Technology of China led a frontier research team to conduct a 30-40 km quantum communication test on the Great Wall in 2005.

Source: Xinhua

Read more: http://www.nanowerk.com/news2/space/newsid=29420.php#ixzz2N3KtTJZN
 
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Quantum Realm: Forging New Pathways to Quantum Devices

Mar. 4, 2013 — Physicists at UC Santa Barbara are manipulating light on superconducting chips, and forging new pathways to building the quantum devices of the future -- including super-fast and powerful quantum computers.

The science behind tomorrow's quantum computing and communications devices is being conducted today at UCSB in what some physicists consider to be one of the world's top laboratories in the study of quantum physics. A team in the lab of John Martinis, UCSB professor of physics, has made a discovery that provides new understanding in the quantum realm and the findings are published this week in Physical Review Letters.

"As one crucial step of achieving controllable quantum devices, we have developed an unprecedented level of manipulating light on a superconducting chip," said first author Yi Yin. Yin worked on the project when she was a postdoctoral fellow in the Martinis Lab from 2009 to 2012. She relocated to her native China last fall, where she is now a professor at Zhejiang University in the city of Hangzhou."

In our experiment, we caught and released photons in and from a superconducting cavity by incorporating a superconducting switch," said Yin. "By controlling the switch on and off, we were able to open and close a door between the confined cavity and the road where photons can transmit. The on/off speed should be fast enough with a tuning time much shorter than the photon lifetime of the cavity."

She explained that not only can the switch be in an on/off state, it also can be opened continuously, like a shutter. In that way, the research team was able to shape the released photons in different wave forms -- a key element for the next step they want to accomplish: controlled photon transfer between two distant cavities.

Co-author Yu Chen, also a postdoctoral fellow in the Martinis lab, said that this way of moving information around -- sending and catching information -- is one of the most important features of this research. "In optics, people imagine sending information from Earth to a satellite and then back -- really remote quantum communication," he said.

"The shutter controls the release of this photon," said Chen. "You need to perfectly transfer a bit of information, and this shutter helps you to do that."

Co-author Jim Wenner, a graduate student in the Martinis lab, explained another application. "Another one, again with communication, would be providing ways to transmit signals in a secure manner over long distances," said Wenner.

He said that, instead of another shutter, Yin used classical electronics to drive the photon. She then captured the signal in the superconducting cavity, in an area called the meander, or the resonator. Then the shutter controlled the release of the photon.

Wenner explained that the resonator, a superconducting cavity, is etched on the flat, superconducting chip -- which is about one quarter of an inch square. It is chilled to a temperature of about minus-273.12 degrees Celsius.

Yin completed her B.S. in physics at the University of Science and Technology in China, before going to Harvard University to earn a Ph.D. in physics. Of the time she spent at UCSB, Yin said: "The Martinis group is one of the best groups in the field of superconducting quantum devices in the world, which strongly attracted me to find the opportunity to work here.

"The whole group is a very young, energetic, and creative team, with the strong leadership and support of Professor John Martinis. I am very happy to have learned the advanced techniques and to have studied the exotic quantum devices of this group." She credits the support of the entire UCSB team, especially important technique support from co-authors Yu Chen, Daniel Sank, Peter O'Malley, Ted White, and Jim Wenner.

In addition to Martinis, the other co-authors from UCSB are Rami Barends, Julian Kelly, Anthony Megrant, Charles Neill, Amit Vainsencher, and Andrew Cleland. Additional contributors are Erik Lucero, now with the IBM T.J. Watson Research Center; Matteo Mariantoni, now with the University of Waterloo, Waterloo, Canada; and Alexander N. Korotkov, with the University of California, Riverside.

Quantum realm: Forging new pathways to quantum devices
 
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Just think, if we had quantum computing, I could check my email and surf PDF almost instantaneously.
 
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Einstein is VASTLY overrated.

Just think, if we had quantum computing, I could check my email and surf PDF almost instantaneously.


try this: if we had quantum entanglement, you could checkmate Kasparov in Moscow and surf in the Gulf of Mexico almost instantaneously. :agree:
 
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i know so many secrets about universe and superior beings but havent found anyone worth it yet to pass my knowledge....

errr...perhaps you should pass on your secrete indoor plumbing knowledge to ISRO to start with, else on their way to Mar they might have to take "Open Air" quite literally I'm afraid...
 
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That'd be nice but unless it involves money or hot women, I'm not really interested. :cheesy:
 
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Einstein is VASTLY overrated.




try this: if we had quantum entanglement, you could checkmate Kasparov in Moscow and surf in the Gulf of Mexico almost instantaneously. :agree:

Even without quantum entanglement, i am sure u could masturbate and watch **** simultaneously.:lol::lol:
 
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Yin completed her B.S. in physics at the University of Science and Technology in China, before going to Harvard University to earn a Ph.D. in physics.

It is an excellent resume!

Great she has returned to China and now working as a prof in prestigious 浙江大学 Zhejiang University
 
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Einstein is VASTLY overrated.

Seeing this work is based effectively on Einstein’s work I doubt the researchers would agree.

In 1935, physicists Albert Einstein, Boris Podolsky and Nathan Rosen (EPR) argued in a now-famous paper that “(t)he quantum mechanical description of physical reality is incomplete”.

According to EPR, “hidden variables” must exist to explain the unintuitive results of experiments with entangled particles.

In 1964, John Bell developed his famous Bell Inequality as the basis to test for the existence of these hidden variables.
 
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Prof. Yi Yin of Zhejiang University,Hangzhou,China.
 
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Now this is what I call a “major breakthrough” in future information technology!!:china::yahoo:

Experimental Observation of the Quantum Anomalous Hall Effect in a Magnetic Topological Insulator
Cui-Zu Chang1,2,*, Jinsong Zhang1,*, Xiao Feng1,2,*, Jie Shen2,*, Zuocheng Zhang1, Minghua Guo1, Kang Li2, Yunbo Ou2, Pang Wei2, Li-Li Wang2, Zhong-Qing Ji2, Yang Feng1, Shuaihua Ji1, Xi Chen1, Jinfeng Jia1, Xi Dai2, Zhong Fang2, Shou-Cheng Zhang3, Ke He2,†, Yayu Wang1,†, Li Lu2, Xu-Cun Ma2, Qi-Kun Xue1,2,†
+ Author Affiliations

1State Key Laboratory of Low-Dimensional Quantum Physics, Department of Physics, Tsinghua University, Beijing 100084, China.
2Beijing National Laboratory for Condensed Matter Physics, Institute of Physics, The Chinese Academy of Sciences, Beijing 100190, China.
3Department of Physics, Stanford University, Stanford, CA 94305–4045, USA.
↵†Corresponding author. E-mail: qkxue@mail.tsinghua.edu.cn (Q.K.X.); kehe@iphy.ac.cn (K.H.); yayuwang@tsinghua.edu.cn (Y.W.)
↵* These authors contributed equally to this work.

Abstract

The quantized version of the anomalous Hall effect has been predicted to occur in magnetic topological insulators, but the experimental realization has been challenging. Here, we report the observation of the quantum anomalous Hall (QAH) effect in thin films of Cr-doped (Bi,Sb)2Te3, a magnetic topological insulator. At zero magnetic field, the gate-tuned anomalous Hall resistance reaches the predicted quantized value of h/e2, accompanied by a considerable drop of the longitudinal resistance. Under a strong magnetic field, the longitudinal resistance vanishes, whereas the Hall resistance remains at the quantized value. The realization of the QAH effect may lead to the development of low-power-consumption electronics.

Experimental Observation of the Quantum Anomalous Hall Effect in a Magnetic Topological Insulator
 
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I actually hope that the progress of Quantum Computing could actually slow down a notch since I might have to go back to school and relearn everything once quantum computers become popular.
 
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