IRISS Teams Up with NIST and DARPA to Test Nobel Prize-Winning Technology
CU researchers Dan Hesselius of the Integrated Remote and In Situ Sensing (IRISS) Initiative and Greg Rieker and Shalom Ruben of the teamed with Kevin Cossel and Nathan Newbury's team at and DARPA to test their ability to track a drone with a comb laser, enabling precise measurement of trace gases. The results of this work were published in , additional information provided by the
The paper outlines how this new technique for the spatial mapping of atmospheric gases has been applied by using precise dual-comb spectroscopy to a retroreflector mounted on a multi-copter. Open path dual-frequency comb spectroscopy (DCS) has shown precise results in measuring pollutants, harmful gases, and greenhouse gases such as carbon dioxide (CO2), water vapor (H2O), and methane (CH4). The DCS system measures atmospheric absorption using thousands of individual frequencies with near infrared laser light. In combination with the DCS system and the unmanned aircraft system (UAS), we can perform accurate measurements revealing the horizontal and vertical spatial profile of these gases.
In the video below, Hesselius flies an X8 quadcopter fitted with a small retro-reflector mirror designed to reflect the back to a base station. Using this reflection, the team is able to make very precise measurements of trace gases. The lower panels of the video show the measurements being made, while the upper left panel tracks the unmanned aircraft as it maneuvers.
The CU Precision Laser Diagnostics Lab helped develop the precision tracking system - the lab, lead by Dr. Greg Rieker, was recently to track methane leaks using this techinology. By utilizing UAS to reflect the comb, researches will be able to measure atmospheric trace gases in more environments, and with more accuracy, than ever before.
In 2005, John L Hall of was awarded the Nobel Prize in Physics for his work on the optical frequency comb technique used by this system.
[video:https://vimeo.com/203358680]