Superconductivity in LEDs sheds new light on quantum entanglement
Entanglement occurs when particles become correlated in pairs to predictably interact with each other regardless of how far apart they are. By measuring the properties of one member of the entangled pair means that you instantly know the properties of the other. Einstein referred to entanglement as “spooky action at a distance.”
“A usual light source such as an LED emits photons randomly without any correlations,” explained Alex Hayat, who is also a Global Scholar at the Canadian
Institute for Advanced Research. “We’ve proved that generating entanglement between photons emitted from an LED can be achieved by adding another peculiar
physical effect of superconductivity – a resistance-free electrical current in certain materials at low temperatures.”
This effect occurs when electrons are entangled in Cooper pairs – a phenomenon in which when one electron spins one way, the other will spin in the opposite direction. When a layer of such superconducting material is placed in close contact with a semiconductor LED structure, Cooper pairs are injected into the LED, so that pairs of entangled electrons create entangled pairs of photons. The effect, however, turns out to work only in LEDs which use nanometer-thick active regions – quantum wells.
“Typically quantum properties show up on very small scales – an electron or an atom. Superconductivity allows quantum effects to show up on large scales – an electrical component or a whole circuit. This quantum behaviour can significantly enhance light emission in general, and entangled photon emission in particular,” explained Hayat.
The research was published in Physical Review B on March 10, 2014.
Related articles and links:
https://journals.aps.org/prb/pdf/10.1103/PhysRevB.89.094508
News articles:
Single-molecule LED breakthrough opens molecular computer opportunities
Atom scale simulation offers nanoscale film growth benefits
If you enjoyed this article, you will like the following ones: don't miss them by subscribing to :
