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Environmentally stable laser emits exceptionally pure light by Staff Writers Washington DC (SPX) Feb 01, 2019
Researchers have developed a compact laser that emits light with extreme spectral purity that doesn't change in response to environmental conditions. The new potentially portable laser could benefit a host of scientific applications, improve clocks for global positioning (GPS) systems, advance the detection of gravitational waves in space and be useful for quantum computing. Researchers from the Massachusetts Institute of Technology's Lincoln Laboratory, USA describe their new laser in Optica, The Optical Society's journal for high impact research. Even if a laser is designed to emit purely in one wavelength, changes in temperature and other environmental factors often introduce noise that causes the light emission to shift or broaden in frequency. The broadened spectral extent of this emission is known as the laser linewidth. The researchers used a new approach to create an optical fiber laser with a spectral linewidth narrower than ever achieved by a fiber or semiconductor laser. The same laser also provides a method to sense and correct for temperature changes as small as 85 nanoKelvin, or 85 billionths of a degree. "Today, ultra-low expansion (ULE) cavity lasers exhibit the narrowest linewidth and highest performance, but they are bulky and very sensitive to environmental noise," said William Loh, the paper's first author. "Our goal is to replace ULE lasers with one that could be portable and isn't sensitive to environmental noise."
Achieving narrow linewidth To make the laser extremely stable in the face of long- and short-term environmental changes, the researchers developed a way to reference the laser signal against itself to sense temperature changes. Their method is highly sensitive compared to other approaches for measuring temperature and allows the calculation of a precise correction signal that can be used to bring the laser back to the emission wavelength of the original temperature. "Temperature is an important contributor to laser noise," said Loh. "A high-quality laser needs to not only have a narrow laser linewidth but also a way to keep that emission stable over the long term."
Improving GPS "We think that atomic clocks based on our stable, narrow linewidth laser could be used to more precisely pinpoint the signal's time of arrival, improving the location accuracy of today's GPS systems," said Loh. "The fact that our laser is compact means it could be used aboard satellites." The laser could also be beneficial for interferometers like the ones used by the Laser Interferometer Gravitational-wave Observatory (LIGO) to detect gravitational waves coming from colliding black holes or collapsing stars. Ultrastable lasers are necessary for this application because laser noise prevents the interferometer from being able to detect the very small perturbations of a gravitational wave. "There are efforts underway to use lasers in space to create longer interferometer arms for gravitational wave observation," said Loh. "Due to its compact size and robustness, our laser might be a candidate for gravitational wave detection in space." The researchers say that although their new laser is robust, it is currently a benchtop system suitable for laboratory use. They are now working to develop smaller packaging for the laser and will incorporate smaller optical components to create a portable version that might be as small as a smartphone.
Research Report: "An Ultra-Narrow Linewidth Brillouin Laser with Nanokelvin Temperature Self-Referencing,"
New technology uses lasers to transmit audible messages to specific people Washington DC (SPX) Jan 24, 2019 Researchers have demonstrated that a laser can transmit an audible message to a person without any type of receiver equipment. The ability to send highly targeted audio signals over the air could be used to communicate across noisy rooms or warn individuals of a dangerous situation such as an active shooter. In The Optical Society (OSA) journal Optics Letters, researchers from the Massachusetts Institute of Technology's Lincoln Laboratory report using two different laser-based methods to transmit ... read more
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