Measuring the Dispersion in Laser Cavity Mirrors using White-Light Interferometry

Terahertz radiation is an emerging field that has far reaching applications. There is a need for portable and affordable terahertz sources that may be used for detection of structural weaknesses in aerospace composites. One possibility for terahertz generation is a femtosecond CrLiSAF laser. However, controlling intracavity dispersion is necessary in order to get the ultrashort pulses needed to generate terahertz radiation. This research measures dispersion of the chirped femtosecond intracavity mirrors by employing white-light interferometry and explains the theory behind the curve-fitting process used to calculate dispersion. To compensate for the narrow reflectivity band of the mirrors, a CaF2 calcium fluoride window was used to increase the number of spectral fringes in the interferogram. A cavity was designed using these mirrors, and the CrLiSAF laser was successfully modelocked.