US EPA

3844501 

Journal Article 

Long-Path Quantum Cascade Laser-Based Sensor for Methane Measurements 

Michel, APM; Miller, DJ; Sun, K; Tao, Lei; Stanton, L; Zondlo, MA 

2016 

Yes 

Journal of Atmospheric and Oceanic Technology
ISSN: 0739-0572
EISSN: 1520-0426 

33 

11 

2373-2384 

10.1175/JTECH-D-16-0024.1 

WOS:000388808000007 

A long-path methane (CH4) sensor was developed and field deployed using an 8-mm quantum cascade laser. The high optical power (40 mW) of the laser allowed for path-integrated measurements of ambient CH4 at total pathlengths from 100 to 1200 m with the use of a retroreflector. Wavelength modulation spectroscopy was used to make high-precision measurements of atmospheric pressure-broadened CH4 absorption over these long distances. An in-line reference cell with higher harmonic detection provided metrics of system stability in rapidly changing and harsh environments. The system consumed less than 100 W of power and required no consumables. The measurements intercompared favorably (typically less than 5% difference) with a commercial in situ methane sensor when accounting for the different spatiotemporal scales of the measurements. The sensor was field deployed for 2 weeks at an arctic lake to examine the robustness of the approach in harsh field environments. Shortterm precision over a 458-m pathlength was 10 ppbv at 1Hz, equivalent to a signal from a methane enhancement above background of 5 ppmv in a 1-m length. The sensor performed well in a range of harsh environmental conditions, including snow, rain, wind, and changing temperatures. These field measurements demonstrate the capabilities of the approach for use in detecting large but highly variable emissions in arctic environments.