The “superradiance” is one of the most surprising and striking phenomena in quantum optics. However, it can be intuitively understood quite easily by imagining an atom as a tiny antenna which can emit light (or more technically, electromagnetic radiation field) under appropriate conditions. “Now imagine that there is a collection of N atoms. When these N atoms are located far from one another and thermally excited, they radiate independently from each other so that the intensity of the emitted light is proportional to the number of the atoms, N”, explains Farokh Mivehvar from the Department of Theoretical Physics of the University of Innsbruck. However, if these atoms are located very closely, the atomic antennae start talking to each other and consequently synchronize with one another, hence emitting light whose intensity goes as the square of the number of the atoms. “One can envisage this situation as the atoms form a single giant antenna which emits light more efficiently”, Farokh Mivehvar continues. “As a result, the atoms emit their energy N times faster than independent atoms.” It is this effect which is referred to as “superradiance”.
On the way to superradiant lasers
In his recent work published in Physical Review Letters, Farokh Mivehvar has theoretically considered “two” collections of atoms, each containing a number of atoms (N1 and N2), inside a quantum cavity. In each ensemble, the atoms are located very closely to each other and can emit light “superradiantly”. “However, it is not obvious a priori how these two giant antennae associated with the two atomic ensembles can emit light simultaneously”, says Mivehvar. This turns out to be non-trivial. “In particular, we find two distinct ways that the two giant antennae can emit light.” In the first way, the two giant antennae cooperate with each other and form a single super-giant antenna, emitting light superradiantly even more so. However, in the second way, the two giant antennae compete with each other destructively, hence suppressing the superradiant light emission. In particular, when the two ensembles have the same number of atoms, the superradiant light emission is completely suppressed. “In addition, we also find cases where the two giant antennae emit light which is a superposition of the two types mentioned before and has an oscillatory character”, says Farokh Mivehvar.
The model and predictions can be implemented and observed in state-of-the-art cavity/waveguide-quantum-electrodynamics experiments. The findings might also have applications in the new generation of so-called superradiant lasers.
Publication: Conventional and Unconventional Dicke Models: Multistabilities and Nonequilibrium Dynamics. Farokh Mivehvar. Phys. Rev. Lett. 132, 073602 DOI: 10.1103/PhysRevLett.132.073602