Preprints
https://doi.org/10.5194/amt-2022-207
https://doi.org/10.5194/amt-2022-207
 
19 Jul 2022
19 Jul 2022
Status: a revised version of this preprint was accepted for the journal AMT and is expected to appear here in due course.

Evaluating the performance of a Picarro G2207-i analyser for high-precision atmospheric O2 measurements

Leigh S. Fleming1, Andrew C. Manning1, Penelope A. Pickers1, Grant L. Forster1,2, and Alex J. Etchells1 Leigh S. Fleming et al.
  • 1Centre for Ocean and Atmospheric Sciences, School of Environmental Sciences, University of East Anglia, Norwich, UK
  • 2National Centre for Atmospheric Science, University of East Anglia, UK

Abstract. Fluxes of oxygen (O2) and carbon dioxide (CO2) in and out of the atmosphere are strongly coupled for terrestrial biospheric exchange processes and fossil fuel combustion but are uncoupled for oceanic air-sea gas exchange. High-precision measurements of both species can therefore provide constraints on the carbon cycle and can be used to quantify fossil fuel CO2 (ffCO2) emission estimates. In the case of O2, however, due to its large atmospheric mole fraction of O2 (~20.9 %) it is very challenging to measure small variations to the degree of precision and accuracy required for these applications. We have tested an atmospheric O2 analyser based on the principle of cavity ring-down spectroscopy (Picarro Inc., model G2207-i), both in the laboratory and at the Weybourne Atmospheric Observatory (WAO) field station in the UK, in comparisons to well-established, pre-existing atmospheric O2 and CO2 measurement systems.

In laboratory tests analysing air in high-pressure cylinders, from the Allan deviation we calculated a precision of ± 1 ppm (1σ standard deviation of 300 seconds mean), and a 24-hour peak-to-peak range of hourly averaged values of 1.2 ppm. These results are close to atmospheric O2 compatibility goals as set by the UN World Meteorological Organization. From measurements of ambient air conducted at WAO we found that the built-in water correction of the G2207-i does not sufficiently correct for the influence of water vapour on the O2 mole fraction. When sample air was pre-dried and employing a 5-hourly baseline correction with a reference gas cylinder, the G2207-i’s results showed an average difference from the established O2 analyser of 13.6 ± 7.5 per meg (over two weeks of continuous measurements). Over the same period, based on measurements of a so-called “target tank” (sometimes known as a “surveillance tank”), analysed for 12 minutes every 7 hours, we calculated a repeatability of ± 5.7 ± 5.6 per meg and a compatibility of ± 10.0 ± 6.7 per meg for the G2207-i. To further examine the G2207-i’s performance in real-world applications we used ambient air measurements of O2 together with concurrent CO2 measurements to calculate ffCO2. Due to the imprecision of the G2207-i, the ffCO2 calculated showed large differences from that calculated from the established system, and had a large uncertainty of ± 13.0 ppm, which was roughly double that from the established system (± 5.8 ppm).

Leigh S. Fleming et al.

Status: closed

Comment types: AC – author | RC – referee | CC – community | EC – editor | CEC – chief editor | : Report abuse
  • RC1: 'Comment on amt-2022-207', Anonymous Referee #1, 01 Aug 2022
  • RC2: 'Comment on amt-2022-207', Anonymous Referee #2, 09 Aug 2022

Status: closed

Comment types: AC – author | RC – referee | CC – community | EC – editor | CEC – chief editor | : Report abuse
  • RC1: 'Comment on amt-2022-207', Anonymous Referee #1, 01 Aug 2022
  • RC2: 'Comment on amt-2022-207', Anonymous Referee #2, 09 Aug 2022

Leigh S. Fleming et al.

Data sets

Datasets for "Evaluating the performance of a Picarro G2207-i analyser for high-precision atmospheric O2 measurements" Fleming, L. S., Manning, A. C., Pickers, P. A., Forster, G. L., and Etchells, A. J. https://doi.org/10.5281/zenodo.6802657

Weybourne Atmospheric Observatory: Long term measurements of atmospheric O2 Forster, G. https://catalogue.ceda.ac.uk/uuid/b3f9714c956f428a840211e0184e23eb

Weybourne Atmospheric Observatory: Longterm measurements of Atmospheric Carbon Dioxide Forster, G. https://catalogue.ceda.ac.uk/uuid/87fc265aab6b4aeb961e62da2cd6ca91

Leigh S. Fleming et al.

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Short summary
Measurements of atmospheric O2 can help constrain the carbon cycle processes and quantify fossil fuel CO2 emissions; however, atmospheric O2 measurement is very challenging, and existing analysers are complex systems to build and maintain. We have tested a new O2 analyser (Picarro Inc. G2207-i) in the laboratory and at Weybourne Atmospheric Observatory. We have found that the G2207-i does not perform as well as an existing O2 analyser from Sable Systems Inc..