Net Drawdown of Greenhouse Gases (CO2, CH4 and N2O) by a Temperate Australian Seagrass Meadow

Seagrasses have some of the highest rates of carbon burial on the planet and have therefore been highlighted as ecosystems for nature-based climate change mitigation. However, information is still needed on the net radiative forcing benefit of seagrasses inclusive of their associated greenhouse gas (GHG) emissions. Here, we report simultaneous estimates of seagrass-associated carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) air-water emissions. Applying in situ sampling within a south-east Australian seagrass ecosystem, this study finds atmospheric GHG emissions from waters above seagrasses to range from - 480 +/- 15.96 to - 16.2 +/- 8.32 mg CO2-equivalents m(2) d(-1) (net uptake), with large temporal and spatial variability. Using a combination of gas specific mass balance equations, dissolved stable carbon isotope values (delta C-13) and in situ time-series data, CO2-e flux is estimated at - 21.74 mg m(2) d(-1). We find that the net release of CH4 (0.44 mu mol m(2) h(-1)) and net uptake of N2O (- 0.06 mu mol m(2) h(-1)) effectively negated each other at 16.12 and - 16.13 mg CO2-e m(2) d(-1), respectively. The results of this study indicate that temperate Australian seagrasses may function as net sinks of atmospheric CO2-e. These results contribute towards filling key emission accounting gaps both in the Australian region, and through the simultaneous measurement of the three key greenhouse gas species.

Automated summary

This study estimates the simultaneous emissions of carbon dioxide, methane, and nitrous oxide from seagrass ecosystems and finds that seagrasses may act as net sinks of atmospheric carbon dioxide.