Ocean acidification: Making new discoveries through National Science Foundation research grants
Acidifying marine ecosystems of increasing concern
With increasing levels of carbon dioxide accumulating in the atmosphere and moving into marine systems, the world's oceans are becoming more acidic.
The oceans may be acidifying faster today than at any time in the past 300 million years, scientists have found.
To address the concern for acidifying marine ecosystems, the National Science Foundation (NSF) has awarded new grants totaling $12 million in its Ocean Acidification Program.
The program is part of NSF's Science, Engineering and Education for Sustainability (SEES) investment.
The awards, the third round in this program, are supported by NSF's Directorates for Geosciences and Biological Sciences.
"These new awards will expand the scope of our knowledge about the types of marine organisms, populations, communities, and ecosystems that may be affected in unique ways by a more acidic ocean," says David Conover, director of NSF's Division of Ocean Sciences.
From tropical oceans to icy seas, the projects will foster research on the nature, extent and effects of ocean acidification on marine environments and organisms in the past, present and future.
"NSF is excited to add these high-quality research projects to our growing ocean acidification award portfolio," says David Garrison, program director in NSF's Directorate for Geosciences and chair of NSF's Ocean Acidification Working Group.
Ocean acidification affects marine ecosystems, organisms' life histories, ocean food webs and biogeochemical cycling, scientists have discovered.
Researchers believe there is a need to understand the chemistry of ocean acidification and its interplay with marine biochemical and physiological processes, before Earth's seas become inhospitable to life as we know it.
Animal species from pteropods--delicate, butterfly-like planktonic drifters--to hard corals are affected by ocean acidification. So, too, are the unseen microbes that fuel ocean productivity and influence the chemistry of ocean waters.
As the oceans become more acidic, the balance of molecules needed for shell-bearing organisms to manufacture shells and skeletons is altered.
The physiology of many marine species, from microbes to fish, may be affected. Myriad chemical reactions and cycles are influenced by the pH, or acidity, of the oceans.
The newly funded projects include studies of whether populations of animals have the genetic capacity to adapt to ocean acidification. The findings, scientists say, will yield new insights about how a future more acidic ocean will affect marine life.
"These awards will extend our understanding of the physiological abilities of organisms to adjust to acidifying oceans in the near-term, and the evolutionary capacities of populations to adapt to predicted ocean acidification in the next century," says William Zamer, program director in NSF's Directorate for Biological Sciences.
Has ocean life faced similar challenges in our planet's past?
"Earth system history informs our understanding of the effects of ocean acidification in the present and the future," says Garrison.
For a true comprehension of how acidification will change the oceans, he says, we need to integrate paleoecology with marine chemistry, physics, ecology and an understanding of the past environmental conditions on Earth.
NSF Ocean Acidification Program grantees will ask questions such as: Will regional differences in marine chemistry and physics increase acidification? Are there complex interactions, cascades and bottlenecks that will emerge as the oceans acidify, and what are their ecosystem implications? And if current trends continue, how far-reaching will the changes be?
NSF 2013 Ocean Acidification awardees, their institutions and projects are:
Stephen Archer, Bigelow Laboratory for Ocean Sciences, Ocean acidification: Influence of ocean acidification on biotic controls of DMS emissions
Additional Collaborators: Patricia Matrai and Peter Countway, Bigelow Laboratory for Ocean Sciences
Andrew Esbaugh, University of Texas Austin, Ocean acidification: Implications for respiratory gas exchange and acid-base balance in estuarine fish
Brian Hopkinson, University of Georgia, Ocean acidification: Coral inorganic carbon processing in response to ocean acidification
Additional Collaborators: Christof Meile, William Fitt and Yongchen Wang, University of Georgia
Janet Kubler, California State University, RUI: Ocean acidification: Scope for resilience to ocean acidification in macroalgae
Additional Collaborators: Steven Dudgeon, California State University
Gareth Lawson, Woods Hole Oceanographic Institution, Ocean acidification: Seasonal and ontogenetic effects of ocean acidication on pteropods in the Gulf of Maine
Additional Collaborators: Ann Tarrant and Amy Maas, Woods Hole Oceanographic Institution
Francois Morel, Princeton University, Ocean acidification: Effect on the availability of divalent trace metals to phytoplankton
James Morris, Michigan State University, Collaborative research: Ocean acidification: Impacts of evolution on the response of phytoplankton populations to rising CO2
Additional Collaborators: Richard Lenski, Michigan State University
Sonya Dyhrman, Columbia University, Collaborative research: Ocean acidification: Impacts of evolution on the response of phytoplankton populations to rising CO2
Michael Follows, Massachusetts Institute of Technology, Collaborative Research: Ocean acidification: Impacts of evolution on the response of phytoplankton populations to rising CO2
Monica Orellana, Institute for Systems Biology, Ocean acidification: A systems biology approach to characterize diatom response to ocean acidification and climate change
Additional Collaborators: Nitin Baliga, Institute for Systems Biology
Brad Seibel, University of Rhode Island, Ocean acidification: Oxygen-limited CO2 tolerance in squids (Ommastrephidaw and Loliginidae)
Wade McGillis, Columbia University, Ocean acidification: Collaborative research: Quantifying the potential for biogeochemical feedbacks to create 'refugia' from ocean acidification on tropical coral reefs
Jennifer Smith, University of California San Diego, Scripps Institution of Oceanography, Ocean acidification: Collaborative research: Quantifying the potential for biogeochemical feedbacks to create 'refugia' from ocean acidification on tropical coral reefs
Additional Collaborators: Todd Martz, University of California, San Diego, Scripps Institution of Oceanography
Steneck, Robert, University of Maine, Century scale impacts to ecosystem structure and function of Aleutian Kelp forests
Axel Timmerman, University of Hawaii, Understanding large-scale patterns of future ocean acidification
Mark Warner, University of Delaware, Ocean acidification: Understanding the impact of CO2 and temperature on the physiological, genetic, and epigenetic response of a model sea anemone system with different symbionts
Additional Collaborators: Adam Marsh, University of Delaware