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Researchers Succeed in Transferring Paradoxical Effect to Laser System

What started out as a mathematical oddity, has now become a new kind of laser technology. Two years ago, physicists at TU Wien predicted a paradoxical laser effect: Under certain conditions, a laser can be switched on not by supplying it with more energy, but by taking energy away from the laser. First experimental signatures of this effect were recently reported at TU Wien.

In collaboration with colleagues at Washington University in St. Louis, USA and at Riken, Japan the researchers have now succeeded in transferring the paradoxical effect to a laser system where it could be studied in detail. The results have now been published in the journal Science.

Two circular Raman lasers are coupled and supplied with energy through an optical fiber (see yellow line). Credit: J. Zhu, B. Peng, S.K. Ozdemir, L. Yang

Switching on by switching off

Matthias Liertzer and Professor Stefan Rotter first discovered the effect in computer simulations. "When two small lasers are placed in close contact with each other, they can influence one another in a way which at first glance seems to contradict any expectation", says Stefan Rotter. "Usually a laser shines when it is supplied with energy. But there are situations in which additional energy can switch off the lasers – and energy loss can turn them on."

In a laser, photons are multiplied. A chain reaction sets in, which eventually produces a strong beam of light. Usually, any kind of loss is highly undesirable. When too much light is lost, for instance through an imperfectly mirrored exterior wall of the laser, the light producing chain reaction comes to a halt and the laser goes out.

Paradoxical behaviour at "exceptional points"

"The properties of the laser can be very well described by a system of mathematical equations", says Matthias Liertzer. "Taking a closer look at these equations, which also model the coupling between lasers, one can see that so-called exceptional points appear. When the mathematical state that describes the laser is close to such an exceptional point, we can observe paradoxical behaviour."

In the experiment, which was carried out by Bo Peng, a graduate student, and Dr. Sahin Kaya Ozdemir, a research scientist, with the research group of Professor Lan Yang in St. Louis, USA two tiny circular lasers were placed next to each other. A thin chromium needle was added to the system, which strongly absorbs light. By accurately adjusting the needle, the amount of loss could be tuned. "The experiments confirmed our predictions: when the system is close to an exceptional point, the absorption of the needle switches the laser on", says Stefan Rotter.

Understanding the mathematical features of these exceptional points could turn out to be useful for quite a few different applications, Rotter believes: "It could be employed for highly sensitive detectors, or for any system consisting of coupled oscillators like in opto-mechanics. There are certainly many interesting effects out there that that can still be explored in connection with exceptional points," says Stefan Rotter.

This news release is available in German.


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