Description
Specifications Table
Product Material – Optical-grade fused silica
Grade – Research-grade
Application – Wavelength measurement, laser mode analysis, spectral resolution
Product Overview
The Fabry-Perot Interferometer is a precision optical instrument designed for high-resolution spectral analysis and wavelength measurement. Constructed with optical-grade fused silica, it ensures minimal thermal expansion and superior stability, making it ideal for demanding research environments. The interferometer operates by creating multiple beam interference between two parallel, highly reflective surfaces, enabling precise wavelength discrimination and laser mode analysis. Its research-grade design guarantees exceptional finesse and contrast, allowing for accurate measurements in spectroscopy, laser tuning, and metrology applications. The robust construction ensures long-term reliability, while the optimized optical path minimizes aberrations, delivering consistent performance across a wide range of experimental setups. Whether used for fundamental physics research or applied optical testing, this interferometer provides the sensitivity and resolution required for cutting-edge experiments.
FAQs
1. What materials are used in the construction of this Fabry-Perot Interferometer?
The interferometer is constructed using optical-grade fused silica, which provides excellent thermal stability and minimal optical distortion for precise measurements.
2. Can this interferometer be used for laser mode analysis?
Yes, the Fabry-Perot Interferometer is specifically designed for laser mode analysis, offering high finesse and resolution to distinguish between longitudinal modes in laser systems.
3. What is the typical finesse value for this interferometer?
The finesse value depends on the reflectivity of the mirrors, but research-grade Fabry-Perot interferometers generally achieve finesse values in the range of 100 to 1000, ensuring sharp transmission peaks.
4. How should this interferometer be stored when not in use?
Store the interferometer in a clean, dry environment, preferably in a protective case to prevent dust accumulation and physical damage. Avoid exposure to temperature fluctuations or humidity.
5. Are there any alternatives to a Fabry-Perot Interferometer for wavelength measurement?
Alternatives include Michelson interferometers, diffraction gratings, and monochromators, but the Fabry-Perot design offers superior resolution for narrow spectral analysis and laser applications.
