Scientists from the MESA+ Institute for Nanotechnology at the University of Twente in the Netherlands have designed a novel type of resonant cavity that serves as a prison for photons. The cavity confines light in all three dimensions in space inside a photonic crystal. The crystals have a structure similar to how atoms are arranged in diamond gems. Confining photons has many applications in optics (efficient miniature lasers and LEDs), communication technology (on-chip storage bits of information), and even in life sciences (tiny, yet sensitive sensors of pharmaceutical materials). The results appear in the journal Physical Review B that is published by the American Physical Society.
In optics, resonant cavities are widely used for their ability to store light in a limited space for a particular duration in time. A generic cavity consists of two mirrors separated by a length of transparent material. Light bounces back and forth between the mirrors. Since light is an electromagnetic wave, it appears that only waves whose wavelength (or color) matches the cavity length can exist in the cavity. This is the result of constructive interference where crests and valleys of many waves coincide to add up to a high intensity. Hence, the allowed waves resonate to form a standing wave in the cavity.
Light does not circulate indefinitely inside a cavity, since on every roundtrip part of the light energy leaks out. An important leakage is caused by the fact that mirrors usually do not reflect light in all directions. In many travel directions of light, it misses a mirror and then escapes the cavity. Such unwanted escape could be halted if one had special mirrors for all three dimensions simultaneously. And this is exactly what the design of the Dutch team employs.
The new design is based on three-dimensional photonic crystals. These structures are well-known for their ability to control the emission and propagation of light. They have a periodic geometry that ensures that a certain color of light is forbidden to exist inside the crystal. The light cannot enter the crystal as it is reflected, no matter in which direction it travels. In an analogy to the properties of semiconductors, this effect is called a “photonic band gap”.
Within the band gap crystal, the forbidden color of light can exist in a small volume, when a point defect is introduced. Since such an optical cavity is surrounded by the photonic band gap crystal—that acts as a three-dimensional mirror for light—light cannot escape: it is locked in a prison.
Making a photonic cavity is challenging since it must be made deep inside a three-dimensional structure, a place that is usually hard to reach. Hence the Twente team came up with a simple design: they employed a diamond-like crystal that is composed of two sets of perpendicular pores, shown in the top image. Such crystals have a record-wide band gap, which provides a strong shielding of the cavity. One pore in each set has a smaller diameter, and at their intersection a point defect appears. Light then becomes imprisoned in a tiny volume about the defect, as indicated by the yellow-colored region in the same image. Extensive computations reveal that the volume of the photon prison is only 2.5 times the wavelength of light cubed (see chart), in other words, as small as one thousandth of one millionth of one millionth of a liter.
Previously, the team had shown that diamond-like photonic band gap crystals can be etched in silicon, with techniques commonly used in the semiconductor chip industry. The new cavity design can be applied during the routine fabrication of these photonic crystals. Thus, it will soon be possible to make a prison for light on a chip. This opens up the exciting prospect to integrate ultrafast photon manipulation with existing electronic information manipulation.
The research has been performed by Dr. Léon Woldering, from the Transducers Science and Technology (TST) chair, and by Prof. Allard Mosk and Prof. Willem Vos from the Complex Photonic Systems (COPS) chair, at the MESA+ Institute for Nanotechnology of the University of Twente in Enschede, The Netherlands. The project was supported by ERC, and the Dutch science agencies NWO, the physics foundation FOM, and technology foundation STW.
Source: Univ. of Twente