Omnidirectional laser could boost microscopy & lidar illumination
Researchers in Eindhoven have developed a new type of low-energy, nanoscale polarition laser that shines in all directions. The key to its omnidirectional light emission is the introduction of something that is usually highly undesirable in nanotechnology: irregularities in the materials.
Because the light produced is brighter than that of LEDs, and the system does not reuqire moving parts, the new laser will be ideal for microscopy lighting and lidar illumination, the researchers have said, although the research requires further development. The results have been published in the journal Physical Review Letters.
Lack of control of the variables determining the response of a system is usually seen as a curse in science and technology. Imperfections and irregularities are unavoidable in nanoscience due to a limited level of control of nanofabrication processes.
The scientists, from Eindhoven University of Technology (TU/e) and the Dutch Institute for Fundamental Energy Research (DIFFER), have investigated the role of imperfections and disorder in nanolasers. By introducing a slight degree of disorder, they have observed a dramatic change: the laser no longer emits in one specific direction, but in all directions.
Development of nanoscale lasers is a very active field of research. In a normal laser, each photon is ‘cloned’ many times in a medium that is located inside a cavity. A different kind of laser is the so-called polariton laser. This works on the principle not of cloning photons but making non-identical photons identical in much the same way as water vapour molecules, moving in all directions with different velocities, are condensed into a single drop. Condensation of photons gives rise to the intense and directional emission characteristic of a laser. An important advantage of polariton lasers is that they have a much lower lasing threshold, which makes them excellent candidates for many applications.
However, a major problem of polariton lasers has been that they need to operate at very low temperatures (like vapour condensation that takes place only when the temperature is lowered) but by using organic materials, it is possible to obtain polariton laser emission even at ambient temperature. The Eindhoven researchers demonstrated last year that they can realise nanoscale polariton lasers that function at ambient temperature, using metallic nanoparticles instead of mirrors as in normal lasers.
The TU/e-DIFFER researchers have now discovered a new kind of polariton laser that consists of a regular pattern of silver nanostripes covered with colored PMMA-polymer whose dye comprises organic emitting molecules. However, the silver stripes deliberately have some degree of imperfection and disorder. The emission from this non-perfect nanolaser is omnidirectional and mainly is determined by the properties of the organic molecules. This result is not expected in the framework of condensation, as omnidirectional emission requires emissions from independent organic molecules instead of the collective emission that is typical for condensation. The demonstration of omnidirectional emission defines new boundaries for the development of nanoscale lasers at ambient temperatures.
The researchers think their laser may eventually be applied in many areas. Compared to a LED, the omnidirectional laser light is much brighter and better defined. That’s why it is a good candidate for microscopy lighting, which currently uses LEDs. Lidar is another potential application, because the light does not require fast moving mirrors in order to cover large areas to image distant objects, thereby significantly reducing the complexity.General illumination is also an option.
'The research is still very fundamental. We hope that our results will stimulate other researchers to improve them by further reducing the lasing threshold or increasing the range of emitted colours,' said lead researcher professor Jaime Gomez Rivas.
The Surface Photonics Group responsible for this work investigates light-matter interaction enhanced by resonant structures, such as metallic nanoparticles and structured surfaces. Strong light-matter coupling leads to new fundamental phenomena that can be exploited to tailor material properties. The group is part of the Photonics and Semiconductor Nanophysics capacity group at the department of Applied Physics and of the “Institute for Integrated Photonics” of Eindhoven University of Technology (TU/e), and formerly part of the Dutch Institute for Fundamental Energy Research (DIFFER), where the experimental work in this paper was performed.