15min:

BRIAN E. BRUMFIELD, Department of Chemistry, University of Illinois at Urbana-Champaign, Urbana, IL 61801; SCOTT S. HOWARD, CLAIRE F. GMACHL, Department of Electrical Engineering, Princeton University, Princeton Institute for the Science and Technology of Materials, Princeton, NJ 08544; DONALD K. WILSON, President, OFR. Division of Thorlabs, Caldwell, NJ 07044; MARK PERCEVAULT, Vice President of Engineering and Manufacturing, OFR. Division of Thorlabs, Caldwell, NJ 07044; BENJAMIN J. MCCALL, Departments of Chemistry and Astronomy, University of Illinois at Urbana-Champaign, Urbana, IL 61801.

In continuous wave cavity ringdown spectroscopy, the precise alignment of a high finesse cavity can introduce disruptive optical feedback into the cw laser source from the cavity back-reflection. This optical feedback can destabilize the laser and significantly impair the mode-hop free tuning range. A general solution to this problem is to use a Faraday rotator in conjunction with a pair of polarizers to optically isolate the cw laser source. Unfortunately there are no commercially available Faraday rotators for use with mid-infrared lasers such as cw-FP-QCLs, which are capable of providing frequency coverage beyond standard difference frequency generation systems. The development of Faraday rotators in the mid-infrared is therefore essential for providing optical isolation for cw-FP-QCLs. We are developing and testing a Faraday rotator at 8.5 µm for use with a cw-FP-QCL laser system built in our laboratory. The end goal is to extend the mode-hop free tuning range of the cw-FP-QCL laser system to assist in the acquisition of high resolution spectra of a mid-infrared band of C₆₀. We will discuss the current progress in the development of an optical isolator to improve the mode-hop free tunability of our cw-FP-QCL system.