Validation of open-path dual-comb spectroscopy against an O<sub>2</sub> background
Nathan Malarich, Brian R. Washburn, Kevin C. Cossel, Griffin Mead, Fabrizio R. Giorgetta, Daniel I. Herman, Nathan R. Newbury, Ian Coddington
Abstract
Dual-comb spectroscopy measures greenhouse gas concentrations over kilometers of open air with high precision. However, the accuracy of these outdoor spectra is challenging to disentangle from the absorption model and the fluctuating, heterogenous concentrations over these paths. Relative to greenhouse gases, O 2 concentrations are well-known and evenly mixed throughout the atmosphere. Assuming a constant O 2 background, we can use O 2 concentration measurements to evaluate the consistency of open-path dual-comb spectroscopy with laboratory-derived absorption models. To this end, we construct a dual-comb spectrometer spanning 1240 nm to 1700nm, which measures O 2 absorption features in addition to CO 2 and CH 4 . O 2 concentration measurements across a 560 m round-trip outdoor path reach 0.1% precision in 10 minutes. Over seven days of shifting meteorology and spectrometer conditions, the measured O 2 has -0.07% mean bias, and 90% of the measurements are within 0.4% of the expected hemisphere-average concentration. The excursions of up to 0.4% seem to track outdoor temperature and humidity, suggesting that accuracy may be limited by the O 2 absorption model or by water interference. This simultaneous O 2 , CO 2 , and CH 4 spectrometer will be useful for measuring accurate CO 2 mole fractions over vertical or many-kilometer open-air paths, where the air density varies.