Quantum computing uses visible light. Current fiber optic cables transmit infrared. Scientists have found a way to ‚Äėtranslate' signals as small as a single photon from one to the other.

Quantum computing has been described as both fast and unhackable. Data is transmitted in bursts of photons. The photons are polarized a certain way. The intended recipient of the transmission knows this way, and has a polarization filter aligned in such a way that it will provide them with a message or a pass code. If anyone between those two people cuts in with a filter of their own, they had better hope it is perfectly aligned with the recipient's filter, or both they and the recipients will receive a garbled message. Not only will they not have what they want, but the recipient will know that their messages are being intercepted.

Security and speed are tempting combinations, but they have to be combined with accessibility. Wavelengths transmitted through cables won't always be the wavelengths that can't be read by the machines their messages are intended for.

A new breakthrough translates the signal from one ‚Äď useless ‚Äď wavelength going in to one understandable wavelength coming out. It does this through Bragg scattering. In Bragg scattering, light hits a lattice of atoms. It scatters off those atoms at the same angle it came in. It results in a predictable interference pattern, which allows scientists to ‚Äėboost' the energy of photons coming down a fiber optic cable in an orderly way. This change in energy becomes a change in wavelength, which can make the photons compatible with the machines they're sent to.

This means a fast, relatively wide, range of signals can be sent over a cable. This color shift becomes a universal translator.


Via Physlink, CSA, and Hyperphysics.