This study investigated the response of metamorphosing larvae of a tubeworm species (Hydroides elegans) to two climate change stressors—ocean acidification (pH 7.6) and low oxygen (hypoxia)—and to both combined. (Laboratory study)

Unlike most marine invertebrates, the common slipper shell broods its embryos in capsules. This study found that the capsules do not protect the embryos from ocean acidification. When brooded under ocean acidification conditions, larvae had shells that were 6 percent shorter, and the percentage of larvae with abnormalities was 1.5- ...

Vegetative growth and production of gametes by kelp from the North Sea (Germany) increased under ocean acidification conditions. (Laboratory study)

When a green seaweed was grown in tidepools for 31 days under ocean acidification conditions, it grew more and had slightly enhanced photosynthesis.

Ocean acidification may alter the biogeographical distribution of a non-calcifying red alga by affecting its photosynthesis and growth. (Laboratory study)

When eelgrass was grown for a year under ocean acidification conditions in outdoor aquaria, they had greater reproductive output, below-ground biomass, and proliferation of new shoots. The findings suggest that ocean acidification will increase the productivity of seagrass meadows. (Laboratory study)

Experiments with deep-sea and shallow-water crab species from the U.S. west coast indicated that deep-sea animals, which are adapted to a stable environment and have reduced metabolic rates, lack the short-term acid–base regulatory capacity to cope with the sudden, large increases in carbon dioxide that would occur if carbon dioxide ...

The Kiel Fjord (Baltic Sea) has large natural variations in carbon dioxide levels. When barnacles from the fjord were raised for 8-12 weeks in warmer seawater under ocean acidification conditions, their growth and condition did not change significantly. Warming increased the shell strength, but ocean acidification conditions had only weak ...

The copepod Calanus finmarchicus had reduced growth, development, and fecundity when exposed to ocean acidification conditions. However, offspring in the next generation did not have delayed development, suggesting that the species may have an ability to adapt to ocean acidification. The results also suggest that in a more acidified ocean ...

Two dominant marine calcifying phytoplankton species, the coccolithophorids Emiliania huxleyi and Gephyrocapsa oceanica, produced less calcite under ocean acidification conditions. They also had more deformities and higher rates of incomplete development. The findings suggest that ocean acidification could slow down the production of calcium carbonate in the ocean. (Laboratory study) ...