Abstract

Global oceans are an important sink of atmospheric carbon dioxide (CO2). Therefore, understanding the air-sea flux ofCO(2) is a vital part in describing the global carbon balance. Eddy covariance (EC) measurements are often used to study CO2 fluxes from both land and ocean. Values of CO2 are usually measured with infrared absorption sensors, which at the same time measure water vapor. Studies have shown that the presence of water vapor fluctuations in the sampling air potentially results in erroneousCO(2) flux measurements resulting from the cross sensitivity of the sensor. Here measured CO2 fluxes from both enclosed-path Li-Cor 7200 sensors and open-path Li-Cor 7500 instruments from an inland measurement site are compared with a marine site. Also, new quality control criteria based on a relative signal strength indicator (RSSI) are introduced. The sampling gas in one of the Li-Cor 7200 instruments was dried by means of a multitube diffusion dryer so that the water vapor fluxes were close to zero. With this setup the effect that cross sensitivity of theCO(2) signal to water vapor can have on theCO(2) fluxes was investigated. The dryer had no significant effect on theCO(2) fluxes. The study tested the hypothesis that the cross-sensitivity effect is caused by hygroscopic particles such as sea salt by spraying a saline solution on the windows of the Li-Cor 7200 instruments during the inland field test. The results confirm earlier findings that sea salt contamination can affect CO2 fluxes significantly and that drying the sampling air for the gas analyzer is an effective method for reducing this signal contamination.

Published in

Journal of Atmospheric and Oceanic Technology
2018, Volume: 35, number: 4, pages: 859-875
Publisher: AMER METEOROLOGICAL SOC

UKÄ Subject classification

Meteorology and Atmospheric Sciences


Publication identifier

DOI: https://doi.org/10.1175/JTECH-D-17-0072.1

Permanent link to this page (URI)

https://res.slu.se/id/publ/105664