Scientists have created a groundbreaking ultra-thin light source that emits pairs of polarization-entangled photons. These specially correlated photons hold immense promise for future quantum technologies, including ultra-secure communication, powerful computation, and high-precision measurements. This light source is particularly small, pure, efficient, and versatile.
Scientists have created a groundbreaking ultra-thin light source that emits pairs of polarization-entangled photons. These specially correlated photons hold immense promise for future quantum technologies, including ultra-secure communication, powerful computation, and high-precision measurements. This light source is particularly small, pure, efficient, and versatile.
Entangled photons share a unique connection. By measuring one photon’s properties, scientists can instantly determine the properties of its entangled partner, regardless of distance. This phenomenon has the potential to revolutionize fields like communication, computation and metrology.
The new light source is made from a special material called 3R-WS2 and is hundreds of times thinner than a human hair. This material allows the light source to be miniaturized and integrated into future quantum photonic circuits.
The researchers achieved this breakthrough by carefully selecting a material with the right properties. The material needs to be able to efficiently generate entangled photons and have a well-defined internal structure. The researchers have identified the rule of material selection for polarization entanglement, facilitating the search for other potential quantum materials with superior performance.
This research represents a significant step forward in developing practical quantum technologies. By creating smaller, more efficient sources of entangled photons, scientists are bringing quantum technology closer to reality.
Journal
eLight
Article Title
Polarization-Entangled Photon-Pair Source with van der Waals 3R-WS₂ Crystal
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