Nonplanner Ring Oscillator Laser Crucial for Gravitational Wave Detection and Quantum Mechanics Experiments

The LN series of narrow linewidth lasers is renowned for its exceptional characteristics, including high spectral purity, a long coherence length, and minimal phase noise. These lasers are meticulously engineered to deliver a stable and precise light output, making them indispensable for a wide range of sophisticated applications.

In the realm of gravitational wave detection, these lasers play a crucial role by providing a stable and coherent light source that is essential for the sensitive instruments used to detect the minute distortions in spacetime caused by passing gravitational waves. Their high spectral purity ensures that the measurements are free from unwanted noise, thereby enhancing the accuracy of the detection process.

For cold atom physics, the LN series lasers offer an ideal light source for manipulating and studying atoms at extremely low temperatures. The long coherence length and low phase noise of these lasers enable researchers to maintain precise control over the atomic states, facilitating groundbreaking experiments in quantum mechanics and precision measurements.

Coherent optical communications also benefit greatly from the use of these narrow linewidth lasers. The high spectral purity ensures that the optical signals remain clear and distinct over long distances, reducing the error rate and increasing the overall efficiency of data transmission. This is particularly important in modern telecommunications, where the demand for high-speed and reliable data transfer is ever-growing.

Optical precision measurements, such as those required in metrology and materials science, rely heavily on the consistent and accurate output of narrow linewidth lasers. The minimal phase noise and long coherence length of the LN series allow for extremely precise measurements of physical quantities, enabling advancements in fields such as nanotechnology and semiconductor manufacturing.

Lastly, in the field of microwave photonic signal processing, these lasers are instrumental in generating stable microwave.

• The measurement accuracy of high-speed ultra-precision laser interferometers is limited by the wavelength stability of the probing laser and the coherence coefficient of the interferometer.
• High-Power Output: 1064nm narrow linewidth light sources provide high-power output, enhancing the coherence coefficient of the interferometer.
• High Wavelength Stability: This improves measurement accuracy significantly.
• By utilizing ultra-narrow linewidth solid-state lasers, the measurement accuracy of laser rangefinders can be elevated to achieve measurement precision below the atomic scale within a range of 300mm.

• High-precision Laser Rangefinder (Michelson Interferometer)
• Laser Frequency Standard Light Source (532 System) (Lead Time: 6 Months, Currently in Prototype Stage)
• Precision Spectral Measurement

• Ultra-narrow Linewidth Laser Seed Source

• Light Source for High-precision
• Laser Rangefinder in Integrated
• Circuits (532 System)