Physicists irreversibly split photons by freezing them in Bose-Einstein condensate

A light beam is usually divided by being directed onto a partially reflecting mirror: Part of the light is then reflected back to create the mirror image. The rest passes through the mirror. “However, this process can be turned around if the experimental set-up is reversed,” says Prof. Dr. Martin Weitz from the Institute of Applied Physics at the University of Bonn. If the reflected light and the part of the light passing through the mirror are sent in the opposite direction, the original light beam can be reconstructed.

The physicist investigates exotic optical quantum states of light. Together with his team and Prof. Dr. Achim Rosch from the Institute for Theoretical Physics at the University of Cologne, Weitz was looking for a new method to generate optical one-way streets by cooling the light particles (photons): As a result of the smaller energy of the photons, the light should collect in various valleys and thereby be irreversibly divided. The physicists used a Bose-Einstein condensate made of photons for this purpose, with which Weitz made a name for himself in 2010 because he was the first to create such a “super-photon.”

A beam of light is thrown back and forth between two mirrors. During this process, the photons collide with dye molecules located between the reflecting surfaces. The dye molecules “swallow” the photons and then spit them out again. “The photons acquire the temperature of the dye solution,” says Weitz. “In the course of this, they cool down to room temperature without getting lost.”

By irradiating the dye solution with a laser, the physicists increase the number of photons between the mirrors. The strong concentration of the light particles combined with simultaneous cooling causes the individual photons to fuse to form a “super photon,” also known as Bose-Einstein condensate.

Two optical valleys “catch” the light

The current experiment by the team of physicists from Bonn and Cologne worked in accordance with this principle. However, one of the two mirrors was not completely flat, but had two small optical valleys. When the light beam enters one of the indents, the distance, and therefore the wavelength, becomes slightly longer. The photons then have a lower energy. These light particles are “cooled” by the dye molecules and then pass into a low-energy state in the valleys.

However, the photons in the indents do not behave like marbles rolling over a corrugated sheet. Marbles roll into the valleys of the corrugated sheet and remain there, separated by the “peaks.” “In our experiment, the two valleys are so close together that a tunnel coupling occurs,” reports lead author Christian Kurtscheid from the Weitz team. It is therefore no longer possible to determine which photons are in which valley. “The photons are held in the two valleys and enter the lowest energy state of the system,” explains Weitz. “This irreversibly splits the light as if it were passing through an intersection at the end of a one-way street, while the light waves remain in lockstep in different indents.”

The scientists hope that this experimental arrangement will make it possible to produce even more complex quantum states that allow the generation of interlaced photonic multi-particle states. “Perhaps quantum computers might one day use this method to communicate with each other and form a kind of quantum Internet,” says Weitz with a view towards the future.

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