The first model for capturing and condensing light under realistic conditions has been realized by a student at EPFL, and published in Physical Review A.
Quantum particles can be divided into two types: fermions and bosons. When cooled down to near-absolute zero temperatures, bosons can condense together into a collective state of matter called a Bose-Einstein condensate where they occupy the same quantum state (e.g. same place and velocity simultaneously). This state of matter allows us to observe remarkable phenomena such as superconductivity – the ability to conduct electric energy with zero resistance. One of the greatest challenges in physics has been to realistically create a Bose-Einstein condensate using photons, which could have significant applications in laser technology. Publishing in Physical Review A, a PhD student at EPFL has developed a realistic theoretical model for condensing photons in three-dimensional cavities.
Can photons condense?
A long-standing question in physics has been whether or not photons – the particles that make up light – can be condensed. The main obstacle is that photons actually have no mass, which is a key requirement for a Bose-Einstein condensate. A proposed solution is to use an optical cavity, which can confine light between two parallel reflective sides, which makes photons behave as if they have mass. However, the straight sides of the cavity allowed light to “leak” out and escape.
In 2010, a paper showed experimentally that photons could be permanently trapped in a cavity with curved sides instead of straight ones. This created a “trapping potential” that kept photons from escaping. But although ground-breaking, developing a much-needed theoretical model from this experiment has always been problematic because it assumes that the whole system is two-dimensional and that the medium between photons (it cannot happen in air) does not affect their condensation.
Modeling photon condensation
Alex Kruchkov, a PhD student at EPFL, developed a mathematical model for condensing light in three-dimensional space and under realistic conditions. Building on the previous models, Kruchkov took into account the medium inside the cavity and the way it would affect the behavior of trapped photons. In addition, he extended the model to consider Bose-Einstein condensate statistics for three-dimensional conditions. His theoretical model of photon condensation corresponded to experimental measurements and demonstrated how light energy can be accumulated in a Bose-Einstein condensate state.
The new model offers a more complete theory of photon Bose-Einstein condensate, which is a new and exciting area of physics. In addition, this phenomenon was observed at room-temperature, which makes it much more accessible to technological implementation than the ultra-low temperatures required for BEC of helium-4 (superfluidity) or laser-cooled atoms. Practically implemented, photon BEC could be applied to develop a new type of lasers.