Insights from year-long measurements of air–water CH4 and CO2 exchange in a coastal environment

Yang, M; Bell, TG; Brown, IJ; Fishwick, J; Kitidis, V; Nightingale, PD; Rees, AP; Smyth, TJ. 2019 Insights from year-long measurements of air–water CH4 and CO2 exchange in a coastal environment. Biogeosciences, 16 (5). 961-978. https://doi.org/10.5194/bg-16-961-2019

[img]
Preview
Text
Yang Seasonal GHG fluxes 2019.pdf - Published Version
Available under License Creative Commons Attribution.

Download (1MB) | Preview
Official URL: http://dx.doi.org/10.5194/bg-16-961-2019

Abstract/Summary

Air–water CH4 and CO2 fluxes were directly measured using the eddy covariance technique at the Penlee Point Atmospheric Observatory on the southwest coast of the United Kingdom from September 2015 to August 2016. The high-frequency, year-long measurements provide unprecedented detail on the variability of these greenhouse gas fluxes from seasonal to diurnal and to semi-diurnal (tidal) timescales. Depending on the wind sector, fluxes measured at this site are indicative of air–water exchange in coastal seas as well as in an outer estuary. For the open-water sector when winds were off the Atlantic Ocean, CH4 flux was almost always positive (annual mean of ∼0.05 mmol m−2 d−1) except in December and January, when CH4 flux was near zero. At times of high rainfall and river flow rate, CH4 emission from the estuarine-influenced Plymouth Sound sector was several times higher than emission from the open-water sector. The implied CH4 saturation (derived from the measured fluxes and a wind-speed-dependent gas transfer velocity parameterization) of over 1000 % in the Plymouth Sound is within range of in situ dissolved CH4 measurements near the mouth of the river Tamar. CO2 flux from the open-water sector was generally from sea to air in autumn and winter and from air to sea in late spring and summer, with an annual mean flux of near zero. A diurnal signal in CO2 flux and implied partial pressure of CO2 in water (pCO2) are clearly observed for the Plymouth Sound sector and also evident for the open-water sector during biologically productive periods. These observations suggest that coastal CO2 efflux may be underestimated if sampling strategies are limited to daytime only. Combining the flux data with seawater pCO2 measurements made in situ within the flux footprint allows us to estimate the CO2 transfer velocity. The gas transfer velocity and wind speed relationship at this coastal location agrees reasonably well with previous open-water parameterizations in the mean but demonstrates considerable variability. We discuss the influences of biological productivity, bottom-driven turbulence and rainfall on coastal air–water gas exchange.

Item Type: Publication - Article
Divisions: Plymouth Marine Laboratory > National Capability categories > Atlantic Meridional Transect
Plymouth Marine Laboratory > National Capability categories > Long-term Multi-Centre LOCATE
Plymouth Marine Laboratory > National Capability categories > Single Centre NC - CLASS
Plymouth Marine Laboratory > National Capability categories > Western Channel Observatory
Plymouth Marine Laboratory > Science Areas > Marine Biochemistry and Observations
Depositing User: Kim Hockley
Date made live: 17 Apr 2019 09:01
Last Modified: 17 Apr 2019 09:01
URI: http://plymsea.ac.uk/id/eprint/8179

Actions (login required)

View Item View Item