Atmospheric Measurement Techniques (Dec 2023)

An open-path observatory for greenhouse gases based on near-infrared Fourier transform spectroscopy

  • T. D. Schmitt,
  • J. Kuhn,
  • J. Kuhn,
  • R. Kleinschek,
  • B. A. Löw,
  • S. Schmitt,
  • W. Cranton,
  • M. Schmidt,
  • S. N. Vardag,
  • S. N. Vardag,
  • F. Hase,
  • D. W. T. Griffith,
  • A. Butz,
  • A. Butz,
  • A. Butz

DOI
https://doi.org/10.5194/amt-16-6097-2023
Journal volume & issue
Vol. 16
pp. 6097 – 6110

Abstract

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Monitoring the atmospheric concentrations of the greenhouse gases (GHG) carbon dioxide (CO2) and methane (CH4) is a key ingredient for fostering our understanding of the mechanisms behind the sources and sinks of these gases and for verifying and quantitatively attributing their anthropogenic emissions. Here, we present the instrumental setup and performance evaluation of an open-path GHG observatory in the city of Heidelberg, Germany. The observatory measures path-averaged concentrations of CO2 and CH4 along a 1.55 km path in the urban boundary layer above the city. We combine these open-path data with local in situ measurements to evaluate the representativeness of these observation types on the kilometer scale. This representativeness is necessary to accurately quantify emissions, since atmospheric models tasked with this job typically operate on kilometer-scale horizontal grids. For the operational period between 8 February and 11 July 2023, we find a precision of 2.7 ppm (0.58 %) and 18 ppb (0.89 %) for the dry-air mole fractions of CO2 (xCO2) and CH4 (xCH4) in 5 min measurements, respectively. After bias correction, the open-path measurements show excellent agreement with the local in situ data under atmospheric background conditions. Both datasets show clear signals of traffic CO2 emissions in the diurnal xCO2 cycle. However, there are particular situations, such as under southeasterly wind conditions, in which the in situ and open-path data reveal distinct differences up to 20 ppm in xCO2, most likely related to their different sensitivity to local emission and transport patterns. Our setup is based on a Bruker IFS 125HR Fourier transform spectrometer, which offers a spacious and modular design providing ample opportunities for future refinements of the technique with respect to finer spectral resolution and wider spectral coverage to provide information on gases such as carbon monoxide and nitrogen dioxide.