Thermo-optical charecterization of lasers material using the thermal lens tecnique

In this work we investigate the thermal properties (diffusivity, conductivity, temperature coefficient of the optical path length change, etc) and loss processes owing to ion-ion interactions in laser glassy and crystalline materials. Since the fluorescence quantum efficiency, , is directly related to these mechanisms that lead to luminescence quenching, the studies were performed mainly observing the effects of these processes on . Thermal lens (TL) spectra were used to determine , energy transfer efficiency between matrix-ion, and to analyze effects of \"dead site\" on . A new method based on the TL technique was proposed to determine q and the temperature coefficient of the optical path length change. This new approach was used to investigate concentration quenching mechanisms in glassy materials. It was also used to study effects of OH radicals and other impurities in Yb3+ doped phosphate glasses. Upconversion Auger processes, which are very important for high power laser systems, were investigated in Nd3+ -doped glasses and crystals. In glasses the study was performed as a function of doping ions. In this study the TL showed to be very sensitive, presenting results with uncertainties much smaller than previous literatures. Following the study of losses, we investigate light induced optical distortion as a function of temperature, excitation power, and polarization in SNB ferroelectric crystal. Using the TL technique, the thermal properties through the phase transition ferroelectric-paraelectric in SBN crystals were investigated. In addition, this thesis significantly contributes for characterization of laser materials with potential applications, considering that severa1 of the loss mechanisms studied here must be considered in laser design. This work also presents the TL technique as a valuable to01 for the present study. (AU)