Title :
Confocal Imaging of Thermal Lensing Induced by Near-IR Laser Radiation in an Artificial Eye
Author :
Vincelette, Rebecca L. ; Oliver, Jeffrey W. ; Rockwell, Benjamin A. ; Thomas, Robert J. ; Welch, Ashley J.
Author_Institution :
Univ. of Texas, Austin, TX, USA
Abstract :
A custom confocal imaging system was built and used to record a probe beam´s spatiotemporal response to a thermal lens induced by a near-IR laser radiation source in a water-filled artificial eye. The IR laser radiation input power levels were varied between 150 and 890 mW at wavelengths of 1110, 1130, 1150 and 1318 nm in order to determine the strength of the resulting thermal lens as a function of time, input power, and wavelength. A high-frame-rate camera captured the probe beam´s logarithmic excitation and exponential decay caused by the thermal lens (supplemental video data are provided). Data showed that for equivalent input powers and beam geometries, thermal lensing was strongest for the 1150-nm laser radiation wavelength followed by 1130, 1318 and 1110 nm.
Keywords :
biological effects of laser radiation; biomedical optical imaging; eye; laser applications in medicine; IR laser radiation input power levels; beam logarithmic excitation; beam logarithmic exponential decay; beam spatiotemporal response; high-frame-rate camera; laser radiation wavelength; near-IR laser radiation source; power 150 mW to 890 mW; thermal lens; thermal lensing confocal imaging; water-filled artificial eye; wavelength 1110 nm to 1318 nm; Cain cell; laser–tissue interaction; nonlinear optics; thermal blooming;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2009.2037441
