English

Continuous regional trace gas source attribution using a field-deployed dual frequency comb spectrometer

Atmospheric and Oceanic Physics 2017-11-23 v1

Abstract

Identification and quantification of trace gas sources is a major challenge for understanding and regulating air quality and greenhouse gas emissions. Current approaches either provide continuous but localized monitoring, or quasi-instantaneous 'snapshot-in-time' regional monitoring. There is a need for emissions detection that provides both continuous and regional coverage, because sources and sinks can be episodic and spatially variable. We field deploy a dual frequency comb laser spectrometer for the first time, enabling an observing system that provides continuous detection of trace gas sources over multiple-square-kilometer regions. Field tests simulating methane emissions from oil and gas production demonstrate detection and quantification of a 1.6 g min^-1 source (approximate emissions from a small pneumatic valve) from a distance of 1 km, and the ability to discern two leaks among a field of many potential sources. The technology achieves the goal of detecting, quantifying, and attributing emissions sources continuously through time, over large areas, and at emissions rates ~1000x lower than current regional approaches. It therefore provides a useful tool for monitoring and mitigating undesirable sources and closes a major information gap in the atmospheric sciences.

Keywords

Cite

@article{arxiv.1711.08067,
  title  = {Continuous regional trace gas source attribution using a field-deployed dual frequency comb spectrometer},
  author = {Sean Coburn and Caroline B. Alden and Robert Wright and Kevin Cossel and Esther Baumann and Gar-Wing Truong and Fabrizio Giorgetta and Colm Sweeney and Nathan R. Newbury and Kuldeep Prasad and Ian Coddington and Gregory B. Rieker},
  journal= {arXiv preprint arXiv:1711.08067},
  year   = {2017}
}

Comments

9 pages, 4 main text figures, 2 main text tables, 5 SI figures

R2 v1 2026-06-22T22:53:23.973Z