Researchers at the University of Sydney have resolved a long-standing problem in microchip-scale lasers by carving what they described as "tiny speed bumps" into the devices’ optical cavity. The integration supports the researchers' pursuit of exceptionally "clean" light, and the result could support future quantum computers, advanced navigation systems, ultra-fast communications networks and precision sensors. Specifically, the work showed a way to eliminate a critical source of noise in Brillouin lasers — a class of light sources known for extraordinary purity, producing an ultranarrow spectrum that is almost a perfect single wavelength of light. Brillouin lasers generate light pure enough to be used in optical atomic clocks, but their potential has been constrained by a phenomenon called Brillouin cascading, in which ‘parasitic modes’ of light emerge and degrade performance. The introduction of Bragg gratings has resolved a longstanding issue with Brillouin lasers. Courtesy of the University of Sydney. “Brillouin lasers are among the most coherent light sources, and you can make them at chip-scale,” said lead author Ryan Russell, a Ph.D. candidate at the University of Sydney Nano Institute and School of Physics. “But once you try to increase their output power, they tend to break up into multiple parasitic modes. These extra modes add noise and steal energy from the fundamental mode, which is the one you want to use. For many real-world applications, that’s quite a problem.” To solve the problem, the Sydney team turned to photonic bandgap engineering. By burning in Bragg gratings, or nanoscale features directly inside the laser’s optical cavity, the researchers created a precise “dead zone” that blocks the formation of parasitic modes at their origin, while not impeding the primary mode. “Think of it as carving tiny speed bumps into the light’s racetrack, preventing the noisy by-products from forming,” said co-author Moritz Merklein, also at Sydney Nano and a researcher in the ARC Centre of Excellence in Optical Microcombs for Breakthrough Science (COMBS). “In simple terms, we’ve learned how to tame the cascade before it even begins,” Merklein said. “The photonic bandgap removes the density of states that these parasitic modes rely on to operate. Without available states, the parasitic processes just cannot take place. It’s like trying to shout into the vacuum of space — the sound has nowhere to go.” When the Bragg grating induces the dead zone, the team observed a six-fold increase in the minimum threshold for Brillouin lasing. This is the minimum energy required to excite laser emission. With cascading inhibited, the researchers measured a 2.5× boost in fundamental laser power, directly demonstrating how the method can unlock better performance. Importantly, the Bragg gratings are reconfigurable: they can be written, erased and re-tuned after creation using only laser light, without needing to refabricate the device. This allows chip-scale lasers to be programmed on demand for low-noise ‘single-mode’ or cascaded ‘multi-mode’ operation. “This is not just a fix for Brillouin lasers,” Russell said. “It’s a general framework for controlling optical processes on photonic chips.” This method for controlling the light flowing through photonic chips could lead to cleaner sources of quantum light and frequency comb lasers. These technologies have emerging applications in communications and advanced navigation technology such as GPS. “The ability to engineer the density of states inside a resonator opens the door to totally new classes of light sources and other advanced photonic technologies,” said Ben Eggleton, research group lead at the University of Sydney and COMBS Chief Investigator. The research was published in APL Photonics (www.doi.org/10.1063/5.0289147).