Add to ORKG41 pagesOver the past 250 years, the composition of Earth's atmosphere has changed as a result of anthropogenic emissions of greenhouse gases. For example, activities such as deforestation, agriculture, and the burning of fossil fuels have produced a 31% increase in the concentration of atmospheric carbon dioxide ([CO2]) since 1750 (IPCC 2001). Earth's atmosphere is linked to the oceans at the sea surface, such that alterations in atmospheric composition are reflected in the water. In particular, atmospheric CO2 exists in equilibrium with dissolved CO2 (CO2(aq)) in the oceans. As the atmospheric [CO2] increases, gas exchange with the oceans causes a concomitant increase in [CO2(aq)], with concentrations rising toward a new equilibrium value...
As CO2 levels in Earth’s atmosphere and oceans steadily rise, varying organismal responses may produ...
In nearshore, soft-sediment habitats of the Salish Sea, eelgrass (Zostera marina L.) meadows have be...
Rising atmospheric CO2 is increasing the availability of dissolved CO2 in the ocean relative to HCO3...
CO2 is a critical and potentially limiting substrate for photosynthesis of both terrestrial and aqua...
Projected increases in dissolved aqueous concentrations of carbon dioxide [CO2(aq)] may have signifi...
Seagrasses account for approximately 10% of the ocean’s total carbon storage, although photosynthesi...
Although environmental requirements of seagrasses have been studied for years, reliable metrics for ...
As CO2 levels in Earth’s atmosphere and oceans steadily rise, varying organismal responses may produ...
Ocean acidification is thought to benefit seagrasses because of increased carbon dioxide (CO2) avail...
Seagrass meadows are one of the most productive ecosystems on the planet, but their photosynthesis r...
Seagrass meadows, common to coastal habitats, have been identified as potential short-term refugia f...
International audienceSeagrass meadows are one of the most productive ecosystems on the planet, but ...
The unprecedented rate of CO2 increase in our atmosphere and subsequent ocean acidification (OA) thr...
Seagrasses account for approximately 10% of the total carbon stored in the ocean, although photosynt...
As CO2 levels in Earth’s atmosphere and oceans steadily rise, varying organismal responses may produ...
In nearshore, soft-sediment habitats of the Salish Sea, eelgrass (Zostera marina L.) meadows have be...
Rising atmospheric CO2 is increasing the availability of dissolved CO2 in the ocean relative to HCO3...
CO2 is a critical and potentially limiting substrate for photosynthesis of both terrestrial and aqua...
Projected increases in dissolved aqueous concentrations of carbon dioxide [CO2(aq)] may have signifi...
Seagrasses account for approximately 10% of the ocean’s total carbon storage, although photosynthesi...
Although environmental requirements of seagrasses have been studied for years, reliable metrics for ...
As CO2 levels in Earth’s atmosphere and oceans steadily rise, varying organismal responses may produ...
Ocean acidification is thought to benefit seagrasses because of increased carbon dioxide (CO2) avail...
Seagrass meadows are one of the most productive ecosystems on the planet, but their photosynthesis r...
Seagrass meadows, common to coastal habitats, have been identified as potential short-term refugia f...
International audienceSeagrass meadows are one of the most productive ecosystems on the planet, but ...
The unprecedented rate of CO2 increase in our atmosphere and subsequent ocean acidification (OA) thr...
Seagrasses account for approximately 10% of the total carbon stored in the ocean, although photosynt...
As CO2 levels in Earth’s atmosphere and oceans steadily rise, varying organismal responses may produ...
In nearshore, soft-sediment habitats of the Salish Sea, eelgrass (Zostera marina L.) meadows have be...
Rising atmospheric CO2 is increasing the availability of dissolved CO2 in the ocean relative to HCO3...