Quantum Communication
Under Construction
What is Entanglement, and can it be used to send infomation at that speed?
Good article describing using polarization to test entanglement and the freedom-of-choice loophole:
https://news.mit.edu/2018/light-ancient-quasars-helps-confirm-quantum-entanglement-0820
The freedom of choice loophole is the possibility that researches can choose factors that support their theories rather than random ones. The experimenters here chose Quasars as random choosers of what angle polorizars were set. What’s entangled in this experiment are the particles they split and send to the two polarizers 1 km apart. The results of entanglement between the photons surpass the Bell limit, which is what Bell calculated would be the maximum result of correlation not caused by normal classical science without quantum entanglement.
Early Chinese Experiment with good details, 1200 KM apart
https://arxiv.org/ftp/arxiv/papers/1707/1707.01339.pdf
Can Entanglement travel faster than the speed of light?
Latest Chinese experiment using the distributed entangled photons. "We perform bell test at space-like separation and without the locality and freedom-of-choice loopholes." Quantum Entanglement Travels measured four magnitudes faster than the speed of light!
https://futurism.com/chinese-physicists-measure-speed-of-quantum-entanglement-2
Can Entanglement send information?
It is said that entanglement cannot be used to send communication faster than light because manipulating a data qbit, as would be required to send a message, breaks the entanglement.
https://quantumxc.com/is-quantum-communication-faster-than-the-speed-of-light/
Yet some seem to claim it works perfectly well. Usually they are refering to encoding data splitting it, and then sending the qbit out to a network.
https://singularityhub.com/2018/12/26/quantum-communication-just-took-a-great-leap-forward/
Are there ways around this?
coming soon
Determining complementary properties with quantum clones
G. S. Thekkadath, R. Y. Saaltink, L. Giner, J. S. Lundeen
In a classical world, simultaneous measurements of complementary properties (e.g. position and momentum) give a system's state. In quantum mechanics, measurement-induced disturbance is largest for complementary properties and, hence, limits the precision with which such properties can be determined simultaneously. It is tempting to try to sidestep this disturbance by copying the system and measuring each complementary property on a separate copy. However, perfect copying is physically impossible in quantum mechanics. Here, we investigate using the closest quantum analog to this copying strategy, optimal cloning. The coherent portion of the generated clones' state corresponds to "twins" of the input system. Like perfect copies, both twins faithfully reproduce the properties of the input system. Unlike perfect copies, the twins are entangled. As such, a measurement on both twins is equivalent to a simultaneous measurement on the input system. For complementary observables, this joint measurement gives the system's state, just as in the classical case. We demonstrate this experimentally using polarized single photons.