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China Quantum Communiations Technology: Cryptography, Radar, Satellite, Teleportation, Network

Factbox: Quantum communication and its application
Source: Xinhua| 2017-06-16 15:30:54|Editor: An



BEIJING, June 16 (Xinhua) -- Chinese scientists on Thursday reported a major breakthrough in quantum communication: A pair of entangled photons over a distance of 1,200 km have been successfully transmitted from space to Earth. The previous record was about 100 km.

What is quantum communication and why should we care about it? The following are some basic introductions about the theory:

Quantum communication is based on the principle of quantum entanglement -- a magnificent phenomenon in which particles are "linked" together in such a way that they affect one another regardless of distance.

Some scientists liken it to two pieces of paper that are distant from each other; if you write on one, the other immediately shows your message. In the quantum entanglement theory, this spectacular connection can happen even when the two particles are separated by a galaxy.

That is what Einstein referred to as "a spooky action at a distance,"

The theory is of great significance for secure communications. In quantum communication, any interference is detectable. Two parties can exchange secret messages by sharing an encryption key encoded in the properties of entangled particles.

The successful transmission of entangled photon pairs this time is carried out by "Micius", the world's first quantum satellite launched by China on Aug. 16, 2016.
http://news.xinhuanet.com/english/2017-06/16/c_136371159.htm

China' s quantum satellite establishes photon entanglement over 1,200 km
Source: Xinhua| 2017-06-16 12:39:09|Editor: Yamei





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Pan Jianwei, chief scientist for the quantum satellite project, speaks at a press conference at the University of Science and Technology of China, in Hefei, east China's Anhui Province, June 16, 2017. A team of Chinese scientists have realized the satellite-based distribution of entangled photon pairs over 1,200 kilometers. The photon pairs were demonstrated to be still entangled after travelling long distances. This satellite-based technology opens up bright prospects for both practical quantum communications and fundamental quantum optics experiments at distances previously inaccessible on the ground, said Pan Jianwei, an academician of the Chinese Academy of Sciences. (Xinhua/Jin Liwang)

HEFEI, June 16 (Xinhua) -- A team of Chinese scientists have realized the satellite-based distribution of entangled photon pairs over 1,200 kilometers. The photon pairs were demonstrated to be still entangled after travelling long distances.

This satellite-based technology opens up bright prospects for both practical quantum communications and fundamental quantum optics experiments at distances previously inaccessible on the ground, said Pan Jianwei, an academician of the Chinese Academy of Sciences.

The achievement was made based on the world' s first quantum satellite, Quantum Experiments at Space Scale (QUESS), also dubbed Micius, launched by China on August 16, 2016, and was published as a cover article in the latest issue of academic journal Science.

This experiment was made through two satellite-to-ground downlinks with a total length varying from 1,600 to 2,400 kilometers. The obtained link efficiency is many times higher than that of the direct bidirectional transmission of the two photons through telecommunication fibers, said Pan, who is also the lead scientist of QUESS.

Quantum entanglement is a phenomenon in quantum physics, which is so confounding that Albert Einstein described it as "spooky action at a distance" in 1948.

Scientists found that when two entangled particles are separated, one particle can somehow affect the action of the far-off twin instantly.

Scientists liken it to two pieces of paper that are distant from each other: if you write on one, the other immediately shows your writing.

The mystery of quantum entanglement has been puzzling scientists since it was detected.

Quantum physicists have a fundamental interest in distributing entangled particles over increasingly long distances and studying the behavior of entanglement under extreme conditions.

In theory, this bizarre connection can exist over any distance, but scientists want to see if there' s some physical limit. "If you want to explore new physics, you must push the limits," Pan said.

Previously, entanglement distribution had only been achieved at a distance up to 100 kilometers due to photon loss in optical fibers or terrestrial free space.

One way to improve the distribution lies in the protocol of quantum repeaters, whose practical usefulness, however, is hindered by the challenges of quantum storage and readout efficiency, Pan said.

Another approach is making use of satellite-based and space-based technologies, as a satellite can conveniently cover two distant locations on Earth. The main advantage of this approach is that most of the photons' transmission path is almost in a vacuum, with almost zero absorption and de-coherence, Pan said.

After feasibility studies, Chinese scientists developed and launched QUESS for the mission of entanglement distribution. Cooperating with QUESS are three ground stations: Delingha Observatory in Qinghai, Nanshan Observatory in Xinjiang and Gaomeigu Observatory in Yunan.

For instance, one photon of an entangled pair was beamed to Delingha and the other to Gaomeigu. The distance between the two ground stations is 1,203 kilometers. The distance between the orbiting satellite and the ground stations varies from 500 to 2,000 kilometers, said Pan.

Due to the fact that the entangled photons cannot be amplified as classical signals, new methods must be developed to reduce the link attenuation in the satellite-to-ground entanglement distribution. To optimize the link efficiency, Chinese scientists combined a narrow beam divergence with a high-bandwidth and a high-precision acquiring, pointing, and tracking (APT) technique.

An accurate transmission of photons between the "server" and the "receiver" is never easy, as the optic axis of the satellite must point precisely toward those of the telescopes in the ground stations, said Zhu Zhencai, QUESS chief designer.

What makes it much harder is that the satellite flying over the Earth at a speed of 8 kilometers per second can be continuously tracked by the ground station for just a few minutes.

"It is like tossing a coin from a plane at 100,000 meters above sea level exactly into the slot of a rotating piggy bank," said Wang Jianyu, QUESS project's chief commander.

The highly sensitive QUESS could make visible from the Earth a match being lit on the Moon, Wang added.

By developing an ultra-bright space-borne two-photon entanglement source and the high-precision APT technology, the team established entanglement between two single photons separated by 1,203 kilometers.

Compared with the previous methods of entanglement distribution by direct transmission of the same two-photon source -- using the best performance and most common commercial telecommunication fibers respectively -- the effective link efficiency of the satellite-based approach is 12 and 17 orders of magnitude higher, Pan said.

He said the distributed entangled photons are readily useful for entanglement-based quantum key distribution, which, so far, is the only way to establish secure keys between two distant locations on Earth without relying on trustful relay.

QUESS is also designed to establish "hack-proof" quantum communications by transmitting uncrackable keys from space to the ground, as well as test quantum teleportation with a ground station in Ali, Tibet.

Pan revealed they also want to see if it' s possible to distribute entanglement between the Earth and the Moon in future
http://news.xinhuanet.com/english/2017-06/16/c_136370736.htm
 
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China hits milestone in race to create hack-proof communications

China has taken a big step forward in its pursuit of a hack-proof communications network.
Chinese researchers say they have used a satellite in space to beam tiny particles over a record-breaking distance, according to an article in the latest issue of research journal Science.


The milestone highlights China's emergence as a major player in quantum technology, a field of science that aims to use subatomic particles in areas like secure communications and medical imaging.

"In terms of quantum communications and satellite technology, certainly the Chinese are in front," said Ben Buchler, professor of physics at Australian National University.

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China's Micius satellite sent photons to ground stations in the mountains of Tibet.


Scientists say quantum communications are highly secure because subatomic particles can be used to create a secret key for the sender and receiver of information. Any attempt to eavesdrop would disturb the particles and be discovered.

Governments and private companies are sinking billions of dollars into research and development of quantum technology. There are plenty of possible uses, from securely distributing military information to protecting the private details of consumers.

China became the first country to launch a quantum technology satellite last year, giving it an edge in the global cybersecurity race. Now, that move is starting to bear fruit.

Related: China launches satellite aimed at hack-proof communications

The satellite -- named "Micius" after an ancient Chinese philosopher and scientist -- beamed pairs of entangled photons to ground stations that lie 1,200 kilometers (745 miles) apart.

Scientists have previously sent entangled photons through fiber optics, but the distance covered was just a few hundred kilometers.

Related: China eclipses U.S. to become undisputed king of supercomputers

But despite China's latest achievement, the effort to build a useable quantum communications network still has a long way to go.

Photons are extremely fragile: they travel more smoothly in the near vacuum of space than in the earth's atmosphere.

The Micius satellite sent photons to ground stations in the mountains of Tibet, reducing the amount of air they had to pass through, according to the Science article.

And even then, the physicists reported that just 1 in 6 million photons were collected at the base stations.
http://money.cnn.com/2017/06/16/technology/china-quantum-satellite-success/index.html
 
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Chinese satellite makes breakthrough in quantum communication

For the first time, a space-based device has successfully distributed a pair of entangled photons to two stations on land


PUBLISHED : Friday, 16 June, 2017, 11:39pm
UPDATED : Saturday, 17 June, 2017, 12:14am

China has carried out the first quantum entanglement from space, according to the team behind the project, in what promises to be a significant step towards a new era of “hack-proof” communication.

The nation’s Micius satellite achieved quantum entanglement between two scientific facilities 1,200km apart on the Tibetan Plateau, according to a paper published in Science magazine on Thursday.

Entanglement refers to a feature of quantum physics whereby two particles separated by a distance are mysteriously linked in existence, so that if the status of one is measured or disturbed, the other changes immediately.

Led by Pan Jianwei, a quantum physicist at the University of Science and Technology of China, the team generated a pair of entangled photons on Micius and distributed one to a receiving station in Delingha and the other to a station in Lijiang.

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One challenge, among many, was to make sure the single photons from the rapidly moving satellite hit a one-metre target at a telescope on the ground.

Each second, the two stations successfully received one pair of the entanglement photons as Micius flew over, according to Wang Jianyu, executive deputy head of the Micius project and a corresponding author of the Science paper. Previous attempts on the ground to carry out such transmissions were limited to a little over a hundred metres in distance.

China hits milestone in developing quantum computer ‘to eclipse all others’

Wang said the breakthrough might soon lead to important applications. “The progress achieved by China will give scientists in other countries more encouragement and hope. It is a small but important step of humans into the quantum age,” he said.

With a quantum internet, messages would be transmitted by entangled particles, and any attempt to eavesdrop would disrupt the message flow and trigger an alert.

“It’s a huge, major achievement,” said Thomas Jennewein, a physicist at the University of Waterloo in Canada. “They started with this bold idea and managed to do it,” he was quoted by Science as saying.

Anton Zeilinger, a physicist at the Austrian Academy of Sciences in Vienna and one of the first to propose the idea of a quantum internet, told Science the experiment “shows that China is making the right decisions”.

“I’m personally convinced that the internet of the future will be based on these quantum principles,” he added.
4d863ecc-52a9-11e7-b896-7f2d3a4d650b_1320x770_233946.jpg






But critics said the technology was still far from practical. For instance, the experiment recovered only about one photon out of every 6 million sent.

Pan said that China would build and launch more satellites in the next few years to address this and other issues, such as day-time communication. The Micius could only communicate with the ground at night because the sunlight interfered with the light signal.

The Chinese team had already solved the day-time communication issue in ground experiments, according to Pan. “In the next five years, we plan to launch some really practical quantum satellites,” he was quoted by Science as saying.

China’s hack-proof quantum satellite leap into space leads the world

Wang said that Micius, the world’s first quantum satellite, had finished all its designated experiments, and more ground-breaking results would be published soon in top research journals.

“Its performance is near-perfect. If the total score is 100, I will give it 98 to 100,” he said.

Other countries have joined the race for space-based quantum communication. The Canadian Space Agency, for instance, recently approved funding for a small quantum satellite, while research teams in Europe and the United States have proposed to mount quantum devices on the International Space Station.


http://www.scmp.com/news/china/poli.../chinese-satellite-makes-breakthrough-quantum

“It’s a huge, major achievement,” said Thomas Jennewein, a physicist at the University of Waterloo in Canada. “They started with this bold idea and managed to do it,” he was quoted by Science as saying.

Anton Zeilinger, a physicist at the Austrian Academy of Sciences in Vienna and one of the first to propose the idea of a quantum internet, told Science the experiment “shows that China is making the right decisions”.

“I’m personally convinced that the internet of the future will be based on these quantum principles,” he added.
 
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Chinese satellite makes breakthrough in quantum communication

For the first time, a space-based device has successfully distributed a pair of entangled photons to two stations on land


PUBLISHED : Friday, 16 June, 2017, 11:39pm
UPDATED : Saturday, 17 June, 2017, 12:14am

China has carried out the first quantum entanglement from space, according to the team behind the project, in what promises to be a significant step towards a new era of “hack-proof” communication.

The nation’s Micius satellite achieved quantum entanglement between two scientific facilities 1,200km apart on the Tibetan Plateau, according to a paper published in Science magazine on Thursday.

Entanglement refers to a feature of quantum physics whereby two particles separated by a distance are mysteriously linked in existence, so that if the status of one is measured or disturbed, the other changes immediately.

Led by Pan Jianwei, a quantum physicist at the University of Science and Technology of China, the team generated a pair of entangled photons on Micius and distributed one to a receiving station in Delingha and the other to a station in Lijiang.

250c8640-52a9-11e7-b896-7f2d3a4d650b_1320x770_233946.jpg






One challenge, among many, was to make sure the single photons from the rapidly moving satellite hit a one-metre target at a telescope on the ground.

Each second, the two stations successfully received one pair of the entanglement photons as Micius flew over, according to Wang Jianyu, executive deputy head of the Micius project and a corresponding author of the Science paper. Previous attempts on the ground to carry out such transmissions were limited to a little over a hundred metres in distance.

China hits milestone in developing quantum computer ‘to eclipse all others’

Wang said the breakthrough might soon lead to important applications. “The progress achieved by China will give scientists in other countries more encouragement and hope. It is a small but important step of humans into the quantum age,” he said.

With a quantum internet, messages would be transmitted by entangled particles, and any attempt to eavesdrop would disrupt the message flow and trigger an alert.

“It’s a huge, major achievement,” said Thomas Jennewein, a physicist at the University of Waterloo in Canada. “They started with this bold idea and managed to do it,” he was quoted by Science as saying.

Anton Zeilinger, a physicist at the Austrian Academy of Sciences in Vienna and one of the first to propose the idea of a quantum internet, told Science the experiment “shows that China is making the right decisions”.

“I’m personally convinced that the internet of the future will be based on these quantum principles,” he added.
4d863ecc-52a9-11e7-b896-7f2d3a4d650b_1320x770_233946.jpg






But critics said the technology was still far from practical. For instance, the experiment recovered only about one photon out of every 6 million sent.

Pan said that China would build and launch more satellites in the next few years to address this and other issues, such as day-time communication. The Micius could only communicate with the ground at night because the sunlight interfered with the light signal.

The Chinese team had already solved the day-time communication issue in ground experiments, according to Pan. “In the next five years, we plan to launch some really practical quantum satellites,” he was quoted by Science as saying.

China’s hack-proof quantum satellite leap into space leads the world

Wang said that Micius, the world’s first quantum satellite, had finished all its designated experiments, and more ground-breaking results would be published soon in top research journals.

“Its performance is near-perfect. If the total score is 100, I will give it 98 to 100,” he said.

Other countries have joined the race for space-based quantum communication. The Canadian Space Agency, for instance, recently approved funding for a small quantum satellite, while research teams in Europe and the United States have proposed to mount quantum devices on the International Space Station.


http://www.scmp.com/news/china/poli.../chinese-satellite-makes-breakthrough-quantum

“It’s a huge, major achievement,” said Thomas Jennewein, a physicist at the University of Waterloo in Canada. “They started with this bold idea and managed to do it,” he was quoted by Science as saying.

Anton Zeilinger, a physicist at the Austrian Academy of Sciences in Vienna and one of the first to propose the idea of a quantum internet, told Science the experiment “shows that China is making the right decisions”.

“I’m personally convinced that the internet of the future will be based on these quantum principles,” he added.
Great news
 
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Great news

Quantum radar

16.06.2017
http://mp.weixin.qq.com/s/ESn7YfdG0pl7uuX5bppl3Q

量子雷达原理样机的验收只能在夜间进行,日落之后的海北高原更加寒冷,项目组把验收专家送往县城的宾馆休息,立即联系相关单位,并连夜在实验舱中整理设备,随时准备恢复试验。终于,在半夜12点左右,供电恢复了。凌晨6点的外场,寒冷、安静,量子雷达的发射端缓缓转动,20公里外的、50公里外的目标一一被探测到,随后,转台转向某角度,屏幕上显示在数百公里外的位置忽然检测出明显的信号,国内首台威力突破百公里量级的同类型雷达样机通过验收!

就在高原湖畔,我们量子雷达研究团队对量子雷达样机进行了远程探测试验,一举突破了同类雷达的探测极限,在国际上首次实现量子层次的远程雷达探测。2016年,美国智库caps援引了我国量子雷达团队的研究进展,指出中国完成了量子雷达样机的远程试验走到了世界的前列。

@AndrewJin :D
 
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Quantum radar

16.06.2017
http://mp.weixin.qq.com/s/ESn7YfdG0pl7uuX5bppl3Q

量子雷达原理样机的验收只能在夜间进行,日落之后的海北高原更加寒冷,项目组把验收专家送往县城的宾馆休息,立即联系相关单位,并连夜在实验舱中整理设备,随时准备恢复试验。终于,在半夜12点左右,供电恢复了。凌晨6点的外场,寒冷、安静,量子雷达的发射端缓缓转动,20公里外的、50公里外的目标一一被探测到,随后,转台转向某角度,屏幕上显示在数百公里外的位置忽然检测出明显的信号,国内首台威力突破百公里量级的同类型雷达样机通过验收!

就在高原湖畔,我们量子雷达研究团队对量子雷达样机进行了远程探测试验,一举突破了同类雷达的探测极限,在国际上首次实现量子层次的远程雷达探测。2016年,美国智库caps援引了我国量子雷达团队的研究进展,指出中国完成了量子雷达样机的远程试验走到了世界的前列。

@AndrewJin :D
The 14th Research Institute of CETC (China Electronic Technology Corporation) is amazing! The AESA radars on 052C/D, 055, Type 001/001A carriers, KJ200/500/2000 AWACS, J20, etc., all developed by 14th Institute. Now even Quantum Radar! I'm wondering what will be the next excitement 14th Institute brings to us:china::china::china:
 
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Chinese city to launch ‘unhackable’ quantum network

Tests on system in Jinan in Shandong province complete and service for nearly 200 users to begin next month, state-run media report


PUBLISHED : Monday, 10 July, 2017, 7:02am
UPDATED : Monday, 10 July, 2017, 10:14am

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Stephen Chen

China’s first citywide commercial communications system using “unhackable” quantum technology is expected to be up and running next month, mainland media reported on Sunday.

Tests on the system in Jinan in the east province of Shandong had been completed and the network would start operations next month to provide extremely secure communication for nearly 200 users, state-run China Central Television reported.

Zhou Fei, assistant to the director at the Jinan Institute of Quantum Technology, said the first users would be in the government, military, finance and electricity sectors.

“This is a milestone for quantum communication in China and the world,” CCTV quoted Zhou as saying.

How quantum satellite launch is helping China develop a communications system that ‘cannot be hacked’

The quantum network uses particles of light to encrypt information. If a third party tries to intercept the information, the particles change characteristics, making it impossible to steal the information without alerting the network. It is understood to be impossible for any computer to decipher a message encrypted by a quantum key.
4b79d936-6488-11e7-badc-596de3df2027_1320x770_235917.JPG






China built its first large-scale quantum communication network in Hefei, Anhui province, in 2012, according to People’s Daily. Work finished last year on the world’s longest land-based quantum link between Beijing and Shanghai, while a number of other big cities including Wuhan, are also building their own quantum networks.

Though also as touted commercially viable, these systems were at least in part sharing existing optical fibre lines with traditional telecommunications networks. The “hybrid” structure might compromise security in some cases.

But the Jinan network was an “exclusive” system dedicated to quantum communications, CCTV reported. The information exchange between two users was protected by more than 4,000 qubits per second to achieve “absolute secrecy”.

Chinese satellite makes breakthrough in quantum communication

The network had more than 50 rounds of tests at terminals in Jinan government agencies and various Communist Party offices. The users were spread across several hundred square kilometres, and the test results were “satisfactory”, the report said.

China last month announced its quantum satellite has successfully distributed a pair of entangled photons to two stations on land.

http://www.scmp.com/news/china/poli...hinese-city-launch-unhackable-quantum-network
 
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First Object Teleported from Earth to Orbit
Researchers in China have teleported a photon from the ground to a satellite orbiting more than 500 kilometers above.
Last year, a Long March 2D rocket took off from the Jiuquan Satellite Launch Centre in the Gobi Desert carrying a satellite called Micius, named after an ancient Chinese philosopher who died in 391 B.C. The rocket placed Micius in a Sun-synchronous orbit so that it passes over the same point on Earth at the same time each day.

Micius is a highly sensitive photon receiver that can detect the quantum states of single photons fired from the ground. That’s important because it should allow scientists to test the technological building blocks for various quantum feats such as entanglement, cryptography, and teleportation.

Today, the Micius team announced the results of its first experiments. The team created the first satellite-to-ground quantum network, in the process smashing the record for the longest distance over which entanglement has been measured. And they’ve used this quantum network to teleport the first object from the ground to orbit.

quantum-orbit.png

Teleportation has become a standard operation in quantum optics labs around the world. The technique relies on the strange phenomenon of entanglement. This occurs when two quantum objects, such as photons, form at the same instant and point in space and so share the same existence. In technical terms, they are described by the same wave function.

The curious thing about entanglement is that this shared existence continues even when the photons are separated by vast distances. So a measurement on one immediately influences the state of the other, regardless of the distance between them.

Back in the 1990s, scientists realized they could use this link to transmit quantum information from one point in the universe to another. The idea is to “download” all the information associated with one photon in one place and transmit it over an entangled link to another photon in another place.

This second photon then takes on the identity of the first. To all intents and purposes, it becomes the first photon. That’s the nature of teleportation and it has been performed many times in labs on Earth.

Teleportation is a building block for a wide range of technologies. “Long-distance teleportation has been recognized as a fundamental element in protocols such as large-scale quantum networks and distributed quantum computation,” says the Chinese team.

In theory, there should be no maximum distance over which this can be done. But entanglement is a fragile thing because photons interact with matter in the atmosphere or inside optical fibers, causing the entanglement to be lost.

As a result, the distance over which scientists have measured entanglement or performed teleportation is severely limited. “Previous teleportation experiments between distant locations were limited to a distance on the order of 100 kilometers, due to photon loss in optical fibers or terrestrial free-space channels,” says the team.

But Micius changes all that because it orbits at an altitude of 500 kilometers, and for most of this distance, any photons making the journey travel through a vacuum. To minimize the amount of atmosphere in the way, the Chinese team set up its ground station in Ngari in Tibet at an altitude of over 4,000 meters. So the distance from the ground to the satellite varies from 1,400 kilometers when it is near the horizon to 500 kilometers when it is overhead.

To perform the experiment, the Chinese team created entangled pairs of photons on the ground at a rate of about 4,000 per second. They then beamed one of these photons to the satellite, which passed overhead every day at midnight. They kept the other photon on the ground

Finally, they measured the photons on the ground and in orbit to confirm that entanglement was taking place, and that they were able to teleport photons in this way. Over 32 days, they sent millions of photons and found positive results in 911 cases. “We report the first quantum teleportation of independent single-photon qubits from a ground observatory to a low Earth orbit satellite—through an up-link channel— with a distance up to 1400 km,” says the Chinese team.

This is the first time that any object has been teleported from Earth to orbit, and it smashes the record for the longest distance for entanglement.

That’s impressive work that sets the stage for much more ambitious goals in the future. “This work establishes the first ground-to-satellite up-link for faithful and ultra-long-distance quantum teleportation, an essential step toward global-scale quantum internet,” says the team.

It also shows China’s obvious dominance and lead in field that, until recently, was led by Europe and the U.S.—Micius would surely have been impressed. But an important question now is how the West will respond.

Ref: arxiv.org/abs/1707.00934: Ground-to-satellite quantum teleportation


First Object Teleported from Earth to Orbit - MIT Technology Review
 
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Not long ago, in the early 1990s, scientists only speculated that teleportation using quantum physics could be possible.

 world's first quantum teleportation outside of a laboratory.

 few steps further: they successfully teleported a photon from Earth to a satellite orbiting more than 500 km (311 mi) away.

 highly sensitive photo receiver capable of detecting the quantum states of single photons fired from the ground. Micius was launched to allow scientists to test various technological building blocks for quantum feats including entanglement, cryptography, and teleportation.

This teleportation feat was announced as one of the first results of these experiments. Not only did the team teleport the first object ever from the ground to orbit, they also created the first satellite-to-ground quantum network, smashing the record for the longest distance for which entanglement has been measured.

 MIT Technology Review. "Previous teleportation experiments between distant locations were limited to a distance on the order of 100 kilometers, due to photon loss in optical fibers or terrestrial free-space channels."

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View photos
quantum teleportation
Science/AAAS" data-reactid="58" style="margin-bottom: 1em;">Science/AAAS

Defining teleportation
What comes to mind when you think of teleportation?

Your brain might conjure images of Scotty beaming up the Enterprise crew in Star Trek, but it's actually quite a different process than sci-fi films present.

Quantum teleportation relies on quantum entanglement — a situation where one set of quantum objects (such as photons) form at the same instant and point in space. In this way, they share the same existence. This shared existence continues even when the photons are separated – meaning a measurement on one immediately influences the state of the other, regardless of the distance between them.

This link can be used to transmit quantum information by "downloading" the information associated with one photon over an entangled link to another photon. This second photon takes on the identity of the first.

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View photos
star trek beyond paramount

Paramount Pictures" data-reactid="88" style="margin-bottom: 1em;">Paramount Pictures

Voilà. Teleportation.

In this particular instance, the Chinese team created entangled pairs of photons on the ground at a rate of about 4,000 per second.

They then beamed one of these photons to the satellite, and kept the other photon on the ground. Finally, they measured the photons on the ground and in orbit to confirm that entanglement was taking place.

It's worth noting that there are some limits to this technology. Transporting anything large, for instance, is a ways off.

In theory, there's also no maximum transportation distance, but entanglement is fragile, and the links can easily be broken.

Despite these limits, this research paves the way for even more ambitious studies of quantum teleportation. "This work establishes the first ground-to-satellite up-link for faithful and ultra-long-distance quantum teleportation, an essential step toward global-scale quantum internet," says the team.


See Also:" data-reactid="96" style="margin-bottom: 1em;">See Also:

 
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7b86e1a3c6b2b77bb86260875d876d32

View photos
earth


Shutterstock" data-reactid="31" style="margin-bottom: 1em;">Shutterstock

Not long ago, in the early 1990s, scientists only speculated that teleportation using quantum physics could be possible.

 world's first quantum teleportation outside of a laboratory.

 few steps further: they successfully teleported a photon from Earth to a satellite orbiting more than 500 km (311 mi) away.

 highly sensitive photo receiver capable of detecting the quantum states of single photons fired from the ground. Micius was launched to allow scientists to test various technological building blocks for quantum feats including entanglement, cryptography, and teleportation.

This teleportation feat was announced as one of the first results of these experiments. Not only did the team teleport the first object ever from the ground to orbit, they also created the first satellite-to-ground quantum network, smashing the record for the longest distance for which entanglement has been measured.

 MIT Technology Review. "Previous teleportation experiments between distant locations were limited to a distance on the order of 100 kilometers, due to photon loss in optical fibers or terrestrial free-space channels."

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Defining teleportation
What comes to mind when you think of teleportation?

Your brain might conjure images of Scotty beaming up the Enterprise crew in Star Trek, but it's actually quite a different process than sci-fi films present.

Quantum teleportation relies on quantum entanglement — a situation where one set of quantum objects (such as photons) form at the same instant and point in space. In this way, they share the same existence. This shared existence continues even when the photons are separated – meaning a measurement on one immediately influences the state of the other, regardless of the distance between them.

This link can be used to transmit quantum information by "downloading" the information associated with one photon over an entangled link to another photon. This second photon takes on the identity of the first.

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Voilà. Teleportation.

In this particular instance, the Chinese team created entangled pairs of photons on the ground at a rate of about 4,000 per second.

They then beamed one of these photons to the satellite, and kept the other photon on the ground. Finally, they measured the photons on the ground and in orbit to confirm that entanglement was taking place.

It's worth noting that there are some limits to this technology. Transporting anything large, for instance, is a ways off.

In theory, there's also no maximum transportation distance, but entanglement is fragile, and the links can easily be broken.

Despite these limits, this research paves the way for even more ambitious studies of quantum teleportation. "This work establishes the first ground-to-satellite up-link for faithful and ultra-long-distance quantum teleportation, an essential step toward global-scale quantum internet," says the team.


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At last, one dream when i studied in university comes close to be true.
 
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