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4. Ocean and Coastal Acidification off New England and Nova Scotia

Author

Gledhill, Dwight K., White, Meredith M., Salisbury, Joseph, Thomas, Helmuth, Mlsna, Ivy, Liebman, Matthew, Mook, Bill, Grear, Jason, Candelmo, Allison C., Chambers, R. Christopher, Gobler, Christopher J., Hunt, Christopher W., King, Andrew L., Price, Nichole N., Signorini, Sergio R., Stancioff, Esperanza, Stymiest, Cassie, Wahle, Richard A., Waller, Jesica D., Rebuck, Nathan D., Wang, Zhaohui A., Capson, Todd L., Morrison, J. Ruairidh, Cooley, Sarah R., and Doney, Scott C.

Published
2015

7. Biogeochemical Effects of Rising Atmospheric CO2 on Terrestrial and Ocean Systems

Author

Moore, David J. P, Cooley, Sarah R, Alin, Simone R, Butman, David E, Clow, David W, French, Nancy H. F, Feely, Richard A, Johnson, Zackary, Keppel-Aleks, Gretchen, Lohrenz, Steven E, Ocko, Ilissa, Shadwick, Elizabeth H, Sutton, Adrienne J, Potter, Christopher S, Takatsuka, Yuki, and Yu, Rita

Subjects
Earth Resources And Remote Sensing
Abstract

Rising carbon dioxide (CO2) has decreased seawater pH at long-term observing stations around the world, including in the open ocean north of Oahu, Hawaii, near Alaska's Aleutian Islands, the Gulf of Maine shore, and on Gray's Reef in the southeastern United States. This ocean acidification process has already affected some marine species and altered fundamental ecosystem processes, and further effects are likely. While atmospheric CO rises at approximately the same rate all over the globe, its non-climate effects on land vary depending on climate and dominant species. In terrestrial ecosystems, rising atmospheric CO concentrations are expected to increase plant photosynthesis, growth, and water-use efficiency, though these effects are reduced when nutrients, drought or other factors limit plant growth. Rising CO would likely change carbon storage and influence terrestrial hydrology and biogeochemical cycling, but concomitant effects on vegetation composition and nutrient feedbacks are challenging to predict, making decadal forecasts uncertain. Consequences of rising atmospheric CO are expected to include difficult-to-predict changes in the ecosystem services that terrestrial and ocean systems provide to humans. For instance, ocean acidification resulting from rising CO has decreased the supply of larvae that sustains commercial shellfish production in the northwestern United States. In addition, CO fertilization (increases) plus warming (decreases) are changing terrestrial crop yields. Continued persistence of uptake of carbon by the land and ocean is uncertain. Climate and environmental change create complex feedbacks to the carbon cycle and it is not clear how feedbacks modulate future effects of rising CO on carbon sinks. These are several mechanisms that could reduce future sink capacity.

Published
2018

11. Quantifying the ecological consequences of climate change in coastal ecosystems.

Author

Schoeman, David S., Bolin, Jessica A., and Cooley, Sarah R.

Subjects
ECOLOGICAL regime shifts, CLIMATE change, EFFECT of human beings on climate change, GREENHOUSE gas mitigation, CLIMATE change denial, ECOSYSTEMS
Abstract

Few coastal ecosystems remain untouched by direct human activities, and none are unimpacted by anthropogenic climate change. These drivers interact with and exacerbate each other in complex ways, yielding a mosaic of ecological consequences that range from adaptive responses, such as geographic range shifts and changes in phenology, to severe impacts, such as mass mortalities, ecological regime shifts and loss of biodiversity. Identifying the role of climate change in these phenomena requires corroborating evidence from multiple lines of evidence, including laboratory experiments, field observations, numerical models and palaeorecords. Yet few studies can confidently quantify the magnitude of the effect attributable solely to climate change, because climate change seldom acts alone in coastal ecosystems. Projections of future risk are further complicated by scenario uncertainty - that is, our lack of knowledge about the degree to which humanity will mitigate greenhouse-gas emissions, or will make changes to the other ways we impact coastal ecosystems. Irrespective, ocean warming would be impossible to reverse before the end of the century, and sea levels are likely to continue to rise for centuries and remain elevated for millennia. Therefore, future risks to coastal ecosystems from climate change are projected to mirror the impacts already observed, with severity escalating with cumulative emissions. Promising avenues for progress beyond such qualitative assessments include collaborative modelling initiatives, such as model intercomparison projects, and the use of a broader range of knowledge systems. But we can reduce risks to coastal ecosystems by rapidly reducing emissions of greenhouse gases, by restoring damaged habitats, by regulating non-climate stressors using climate-smart conservation actions, and by implementing inclusive coastalzone management approaches, especially those involving nature-based solutions. [ABSTRACT FROM AUTHOR]

Published
2023
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13. State of the Carbon Cycle - Consequences of Rising Atmospheric CO2

Author

Moore, David J, Cooley, Sarah R, Alin, Simone R, Brown, Molly, Butman, David E, French, Nancy H. F, Johnson, Zackary I, Keppel-Aleks, Lohrenz, Steven E, Ocko, Ilissa, Shadwick, Elizabeth H, Sutton, Adrienne J, Potter, Christopher S, and Yu, Rita M. S

Subjects
Earth Resources And Remote Sensing
Abstract

The rise of atmospheric CO2, largely attributable to human activity through fossil fuel emissions and land-use change, has been dampened by carbon uptake by the ocean and terrestrial biosphere. We outline the consequences of this carbon uptake as direct and indirect effects on terrestrial and oceanic systems and processes for different regions of North America and the globe. We assess the capacity of these systems to continue to act as carbon sinks. Rising CO2 has decreased seawater pH; this process of ocean acidification has impacted some marine species and altered fundamental ecosystem processes with further effects likely. In terrestrial ecosystems, increased atmospheric CO2 causes enhanced photosynthesis, net primary production, and increased water-use efficiency. Rising CO2 may change vegetation composition and carbon storage, and widespread increases in water use efficiency likely influence terrestrial hydrology and biogeochemical cycling. Consequences for human populations include changes to ecosystem services including cultural activities surrounding land use, agricultural or harvesting practices. Commercial fish stocks have been impacted and crop production yields have been changed as a result of rising CO2. Ocean and terrestrial effects are contingent on, and feedback to, global climate change. Warming and modified precipitation regimes impact a variety of ecosystem processes, and the combination of climate change and rising CO2 contributes considerable uncertainty to forecasting carbon sink capacity in the ocean and on land. Disturbance regime (fire and insects) are modified with increased temperatures. Fire frequency and intensity increase, and insect lifecycles are disrupted as temperatures move out of historical norms. Changes in disturbance patterns modulate the effects of rising CO2 depending on ecosystem type, disturbance frequency, and magnitude of events. We discuss management strategies designed to limit the rise of atmospheric CO2 and reduce uncertainty in forecasts of decadal and centennial feedbacks of rising atmospheric CO2 on carbon storage.

Published
2016

14. Towards improved socio-economic assessments of ocean acidification's impacts

Author

Hilmi, Nathalie, Allemand, Denis, Dupont, Sam, Safa, Alain, Haraldsson, Gunnar, Nunes, Paulo A.L.D., Moore, Chris, Hattam, Caroline, Reynaud, Stephanie, Hall-Spencer, Jason M., Fine, Maoz, Turley, Carol, Jeffree, Ross, Orr, James, Munday, Philip L., and Cooley, Sarah R.

Subjects
Social economics -- Research, Ocean acidification -- Research, Environmental impact analysis -- Methods, Biological sciences
Abstract

Ocean acidification is increasingly recognized as a component of global change that could have a wide range of impacts on marine organisms, the ecosystems they live in, and the goods and services they provide humankind. Assessment of these potential socio-economic impacts requires integrated efforts between biologists, chemists, oceanographers, economists and social scientists. But because ocean acidification is a new research area, significant knowledge gaps are preventing economists from estimating its welfare impacts. For instance, economic data on the impact of ocean acidification on significant markets such as fisheries, aquaculture and tourism are very limited (if not non-existent), and non-market valuation studies on this topic are not yet available. Our paper summarizes the current understanding of future OA impacts and sets out what further information is required for economists to assess socio-economic impacts of ocean acidification. Our aim is to provide clear directions for multidisciplinary collaborative research., Introduction The ocean reservoir of carbon is much greater than the terrestrial and atmospheric systems combined and provides an important net sink for carbon through exchanges of C[O.sub.2] with the [...]

Published
2013
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15. The Impacts of Ocean Acidification on Marine Ecosystems and Reliant Human Communities.

Author

Doney, Scott C., Busch, D. Shallin, Cooley, Sarah R., and Kroeker, Kristy J.

Subjects
OCEAN acidification, SCIENTIFIC knowledge, MARINE ecology, ACID-base chemistry, POPULATION dynamics, CARBON cycle, ATMOSPHERIC carbon dioxide, DEFORESTATION
Abstract

Rising atmospheric carbon dioxide (CO2) levels, from fossil fuel combustion and deforestation, along with agriculture and land-use practices are causing wholesale increases in seawater CO2 and inorganic carbon levels; reductions in pH; and alterations in acid-base chemistry of estuarine, coastal, and surface open-ocean waters. On the basis of laboratory experiments and field studies of naturally elevated CO2 marine environments, widespread biological impacts of human-driven ocean acidification have been posited, ranging from changes in organism physiology and population dynamics to altered communities and ecosystems. Acidification, in conjunction with other climate change–related environmental stresses, particularly under future climate change and further elevated atmospheric CO2 levels, potentially puts at risk many of the valuable ecosystem services that the ocean provides to society, such as fisheries, aquaculture, and shoreline protection. Thisreview emphasizes both current scientific understanding and knowledge gaps, highlighting directions for future research and recognizing the information needs of policymakers and stakeholders. [ABSTRACT FROM AUTHOR]

Published
2020
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16. Potential socioeconomic impacts from ocean acidification and climate change effects on Atlantic Canadian fisheries.

Author

Wilson, Tyler J. B., Cooley, Sarah R., Tai, Travis C., Cheung, William W. L., and Tyedmers, Peter H.

Subjects
*OCEAN acidification, *CLIMATE change, *SHELLFISH fisheries, *FISHERIES, *SOCIAL impact, *SPECIES distribution, *SMALL-scale fisheries
Abstract

Ocean acidification is an emerging consequence of anthropogenic carbon dioxide emissions. The full extent of the biological impacts are currently not entirely defined. However, it is expected that invertebrate species that rely on the mineral calcium carbonate will be directly affected. Despite the limited understanding of the full extent of potential impacts and responses there is a need to identify potential pathways for human societies to be affected by ocean acidification. Research on these social implications is a small but developing field. This research contributes to this field by using an impact assessment framework, informed by a biophysical model of future species distributions, to investigate potential impacts facing Atlantic Canadian society from potential changes in shellfish fisheries driven by ocean acidification and climate change. New Brunswick and Nova Scotia are expected to see declines in resource accessibility but are relatively socially insulated from these changes. Conversely, Prince Edward Island, along with Newfoundland and Labrador are more socially vulnerable to potential losses in fisheries, but are expected to experience relatively minor net changes in access. [ABSTRACT FROM AUTHOR]

Published
2020
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17. Projected impacts of future climate change, ocean acidification, and management on the US Atlantic sea scallop (Placopecten magellanicus) fishery.

Author

Rheuban, Jennie E., Doney, Scott C., Cooley, Sarah R., and Hart, Deborah R.

Subjects
OCEAN acidification, PLACOPECTEN magellanicus fisheries, EMISSIONS (Air pollution), CLIMATE change mitigation, SCALLOP industry
Abstract

Ocean acidification has the potential to significantly impact both aquaculture and wild-caught mollusk fisheries around the world. In this work, we build upon a previously published integrated assessment model of the US Atlantic Sea Scallop (Placopecten magellanicus) fishery to determine the possible future of the fishery under a suite of climate, economic, biological, and management scenarios. We developed a 4x4x4x4 hypercube scenario framework that resulted in 256 possible combinations of future scenarios. The study highlights the potential impacts of ocean acidification and management for a subset of future climate scenarios, with a high CO2 emissions case (RCP8.5) and lower CO2 emissions and climate mitigation case (RCP4.5). Under RCP4.5 and the highest impact and management scenario, ocean acidification has the potential to reduce sea scallop biomass by approximately 13% by the end of century; however, the lesser impact scenarios cause very little change. Under RCP8.5, sea scallop biomass may decline by more than 50% by the end of century, leading to subsequent declines in industry landings and revenue. Management-set catch limits improve the outcomes of the fishery under both climate scenarios, and the addition of a 10% area closure increases future biomass by more than 25% under the highest ocean acidification impacts. However, increased management still does not stop the projected long-term decline of the fishery under ocean acidification scenarios. Given our incomplete understanding of acidification impacts on P. magellanicus, these declines, along with the high value of the industry, suggest population-level effects of acidification should be a clear research priority. Projections described in this manuscript illustrate both the potential impacts of ocean acidification under a business-as-usual and a moderately strong climate-policy scenario. We also illustrate the importance of fisheries management targets in improving the long-term outcome of the P. magellanicus fishery under potential global change. [ABSTRACT FROM AUTHOR]

Published
2018
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18. A decision support tool for response to global change in marine systems: the IMBER- ADApT Framework.

Author

Bundy, Alida, Chuenpagdee, Ratana, Cooley, Sarah R, Defeo, Omar, Glaeser, Bernhard, Guillotreau, Patrice, Isaacs, Moenieba, Mitsutaku, Makino, and Perry, R Ian

Subjects
DECISION support systems, GLOBAL environmental change, MARINE ecology, FISH habitats, STAKEHOLDERS
Abstract

Global change is occurring now, often with consequences far beyond those anticipated. Although there is a wide range of assessment approaches available to address-specific aspects of global change, there is currently no framework to identify what governance responses have worked and where, what has facilitated change and what preventative options are possible. To respond to this need, we present an integrated assessment framework that builds on knowledge learned from past experience of responses to global change in marine systems, to enable decision-makers, researchers, managers and local stakeholders to: (i) make decisions efficiently; (ii) triage and improve their responses; and (iii) evaluate where to most effectively allocate resources to reduce vulnerability and enhance resilience of coastal people. This integrated assessment framework, IMBER- ADApT is intended to enable and enhance decision-making through the development, a typology of case-studies providing lessons on how the natural, social and governance systems respond to the challenges of global change. The typology is developed from a database of case-studies detailing the systems affected by change, responses to change and, critically, an appraisal of these responses, generating knowledge-based solutions that can be applied to other comparable situations. Fisheries, which suffer from multiple pressures, are the current focus of the proposed framework, but it could be applied to a wide range of global change issues. IMBER- ADApT has the potential to contribute to timely, cost-effective policy and governing decision-making and response. It offers cross-scale learning to help ameliorate, and eventually prevent, loss of livelihoods, food sources and habitat. [ABSTRACT FROM AUTHOR]

Published
2016
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19. Coral Reefs and People in a High-CO2 World: Where Can Science Make a Difference to People?

Author

Pendleton, Linwood, Comte, Adrien, Langdon, Chris, Ekstrom, Julia A., Cooley, Sarah R., Suatoni, Lisa, Beck, Michael W., Brander, Luke M., Burke, Lauretta, Cinner, Josh E., Doherty, Carolyn, Edwards, Peter E. T., Gledhill, Dwight, Jiang, Li-Qing, van Hooidonk, Ruben J., Teh, Louise, Waldbusser, George G., and Ritter, Jessica

Subjects
ATMOSPHERIC carbon dioxide, CORAL reef ecology, OCEAN acidification, OCEAN temperature, ENVIRONMENTAL mapping, ENVIRONMENTAL engineering
Abstract

Reefs and People at Risk: Increasing levels of carbon dioxide in the atmosphere put shallow, warm-water coral reef ecosystems, and the people who depend upon them at risk from two key global environmental stresses: 1) elevated sea surface temperature (that can cause coral bleaching and related mortality), and 2) ocean acidification. These global stressors: cannot be avoided by local management, compound local stressors, and hasten the loss of ecosystem services. Impacts to people will be most grave where a) human dependence on coral reef ecosystems is high, b) sea surface temperature reaches critical levels soonest, and c) ocean acidification levels are most severe. Where these elements align, swift action will be needed to protect people’s lives and livelihoods, but such action must be informed by data and science. An Indicator Approach: Designing policies to offset potential harm to coral reef ecosystems and people requires a better understanding of where CO2-related global environmental stresses could cause the most severe impacts. Mapping indicators has been proposed as a way of combining natural and social science data to identify policy actions even when the needed science is relatively nascent. To identify where people are at risk and where more science is needed, we map indicators of biological, physical and social science factors to understand how human dependence on coral reef ecosystems will be affected by globally-driven threats to corals expected in a high-CO2 world. Western Mexico, Micronesia, Indonesia and parts of Australia have high human dependence and will likely face severe combined threats. As a region, Southeast Asia is particularly at risk. Many of the countries most dependent upon coral reef ecosystems are places for which we have the least robust data on ocean acidification. These areas require new data and interdisciplinary scientific research to help coral reef-dependent human communities better prepare for a high CO2 world. [ABSTRACT FROM AUTHOR]

Published
2016
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20. An Integrated Assessment Model for Helping the United States Sea Scallop (Placopecten magellanicus) Fishery Plan Ahead for Ocean Acidification and Warming.

Author

Cooley, Sarah R., Rheuban, Jennie E., Hart, Deborah R., Luu, Victoria, Glover, David M., Hare, Jonathan A., and Doney, Scott C.

Subjects
*PLACOPECTEN magellanicus, *FISHERY management, *OCEAN acidification, *GLOBAL warming, *ATMOSPHERIC carbon monoxide
Abstract

Ocean acidification, the progressive change in ocean chemistry caused by uptake of atmospheric CO2, is likely to affect some marine resources negatively, including shellfish. The Atlantic sea scallop (Placopecten magellanicus) supports one of the most economically important single-species commercial fisheries in the United States. Careful management appears to be the most powerful short-term factor affecting scallop populations, but in the coming decades scallops will be increasingly influenced by global environmental changes such as ocean warming and ocean acidification. In this paper, we describe an integrated assessment model (IAM) that numerically simulates oceanographic, population dynamic, and socioeconomic relationships for the U.S. commercial sea scallop fishery. Our primary goal is to enrich resource management deliberations by offering both short- and long-term insight into the system and generating detailed policy-relevant information about the relative effects of ocean acidification, temperature rise, fishing pressure, and socioeconomic factors on the fishery using a simplified model system. Starting with relationships and data used now for sea scallop fishery management, the model adds socioeconomic decision making based on static economic theory and includes ocean biogeochemical change resulting from CO2 emissions. The model skillfully reproduces scallop population dynamics, market dynamics, and seawater carbonate chemistry since 2000. It indicates sea scallop harvests could decline substantially by 2050 under RCP 8.5 CO2 emissions and current harvest rules, assuming that ocean acidification affects P. magellanicus by decreasing recruitment and slowing growth, and that ocean warming increases growth. Future work will explore different economic and management scenarios and test how potential impacts of ocean acidification on other scallop biological parameters may influence the social-ecological system. Future empirical work on the effect of ocean acidification on sea scallops is also needed. [ABSTRACT FROM AUTHOR]

Published
2015
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21. Vulnerability and adaptation of US shellfisheries to ocean acidification.

Author

Ekstrom, Julia A., Gledhill, Dwight, Wellman, Katharine, Beck, Michael W., Brander, Luke M., Edwards, Peter E. T., Portela, Rosimeiry, Suatoni, Lisa, Cooley, Sarah R., Pendleton, Linwood H., Waldbusser, George G., Cinner, Josh E., Ritter, Jessica, Rittschof, Dan, Doherty, Carolyn, Langdon, Chris, and van Hooidonk, Ruben

Subjects
OCEAN acidification, SHELLFISH fisheries, FISHERIES & the environment, COASTAL ecology, ARAGONITE, MARINE ecology
Abstract

Ocean acidification is a global, long-term problem whose ultimate solution requires carbon dioxide reduction at a scope and scale that will take decades to accomplish successfully. Until that is achieved, feasible and locally relevant adaptation and mitigation measures are needed. To help to prioritize societal responses to ocean acidification, we present a spatially explicit, multidisciplinary vulnerability analysis of coastal human communities in the United States. We focus our analysis on shelled mollusc harvests, which are likely to be harmed by ocean acidification. Our results highlight US regions most vulnerable to ocean acidification (and why), important knowledge and information gaps, and opportunities to adapt through local actions. The research illustrates the benefits of integrating natural and social sciences to identify actions and other opportunities while policy, stakeholders and scientists are still in relatively early stages of developing research plans and responses to ocean acidification. [ABSTRACT FROM AUTHOR]

Published
2015
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22. Nutrition and income from molluscs today imply vulnerability to ocean acidification tomorrow.

Author

Cooley, Sarah R, Lucey, Noelle, Kite-Powell, Hauke, and Doney, Scott C

Subjects
*FISH nutrition, *MOLLUSKS, *PSYCHOLOGICAL vulnerability, *OCEAN acidification, *ATMOSPHERIC carbon dioxide
Abstract

Atmospheric carbon dioxide (CO2) emissions from human industrial activities are causing a progressive alteration of seawater chemistry, termed ocean acidification, which has decreased seawater pH and carbonate ion concentration markedly since the Industrial Revolution. Many marine organisms, like molluscs and corals, build hard shells and skeletons using carbonate ions, and they exhibit negative overall responses to ocean acidification. This adds to other chronic and acute environmental pressures and promotes shifts away from calcifier-rich communities. In this study, we examine the possible implications of ocean acidification on mollusc harvests worldwide by examining present production, consumption and export and by relating those data to present and future surface ocean chemistry forecast by a coupled climate-ocean model (Community Climate System 3.1; CCSM3). We identify the 'transition decade' when future ocean chemistry will distinctly differ from that of today (2010), and when mollusc harvest levels similar to those of the present cannot be guaranteed if present ocean chemistry is a significant determinant of today's mollusc production. We assess nations' vulnerability to ocean acidification-driven decreases in mollusc harvests by comparing nutritional and economic dependences on mollusc harvests, overall societal adaptability, and the amount of time until the transition decade. Projected transition decades for individual countries will occur 10-50 years after 2010. Countries with low adaptability, high nutritional or economic dependence on molluscs, rapidly approaching transition decades or rapidly growing populations will therefore be most vulnerable to ocean acidification-driven mollusc harvest decreases. These transition decades suggest how soon nations should implement strategies, such as increased aquaculture of resilient species, to help maintain current per capita mollusc harvests. [ABSTRACT FROM AUTHOR]

Published
2012
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25. ANTICIPATING OCEAN ACIDIFICATION'S ECONOMIC CONSEQUENCES ON COMMERCIAL FISHERIES.

Author

COOLEY, SARAH R. and DONEY, SCOTT C.

Subjects
WATER acidification, OCEAN, ECONOMIC impact, FISHERIES, AQUACULTURE, FISHING villages
Abstract

MANY VALUABLE COMMERCIAL FISHERIES AND AQUACULTURE FACILITIES harvest ocean shellfish (e.g., clams, scallops) and crustaceans (e.g., lobsters, crabs) that form calcium carbonate shells. These animals, along with corals, may be particularly sensitive to changes in seawater chemistry driven by human fossil fuel use. Finfish may also be affected indirectly owing to loss of prey and habitat. Ocean acidification impacts could decrease future fishing revenues and harm communities that depend economically and culturally on marine resources. [ABSTRACT FROM AUTHOR]

Published
2009

27. Recommended priorities for research on ecological impacts of ocean and coastal acidification in the U.S. Mid-Atlantic.

Author

Saba, Grace K., Goldsmith, Kaitlin A., Cooley, Sarah R., Grosse, Daniel, Meseck, Shannon L., Miller, A. Whitman, Phelan, Beth, Poach, Matthew, Rheault, Robert, St.Laurent, Kari, Testa, Jeremy M., Weis, Judith S., and Zimmerman, Richard

Subjects
*ECOLOGICAL impact, *OCEAN acidification, *ACCLIMATIZATION, *SERVICE economy, *CONTINENTAL shelf, *DYNAMICAL systems
Abstract

The estuaries and continental shelf system of the United States Mid-Atlantic are subject to ocean acidification driven by atmospheric CO 2 , and coastal acidification caused by nearshore and land-sea interactions that include biological, chemical, and physical processes. These processes include freshwater and nutrient input from rivers and groundwater; tidally-driven outwelling of nutrients, inorganic carbon, alkalinity; high productivity and respiration; and hypoxia. Hence, these complex dynamic systems exhibit substantial daily, seasonal, and interannual variability that is not well captured by current acidification research on Mid-Atlantic organisms and ecosystems. We present recommendations for research priorities that target better understanding of the ecological impacts of acidification in the U. S. Mid-Atlantic region. Suggested priorities are: 1) Determining the impact of multiple stressors on our resource species as well as the magnitude of acidification; 2) Filling information gaps on major taxa and regionally important species in different life stages to improve understanding of their response to variable temporal scales and sources of acidification; 3) Improving experimental approaches to incorporate realistic environmental variability and gradients, include interactions with other environmental stressors, increase transferability to other systems or organisms, and evaluate community and ecosystem response; 4) Determining the capacity of important species to acclimate or adapt to changing ocean conditions; 5) Considering multi-disciplinary, ecosystem-level research that examines acidification impacts on biodiversity and biotic interactions; and 6) Connecting potential acidification-induced ecological impacts to ecosystem services and the economy. These recommendations, while developed for the Mid-Atlantic, can be applicable to other regions will help align research towards knowledge of potential larger-scale ecological and economic impacts. [ABSTRACT FROM AUTHOR]

Published
2019
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28. Coral Reefs and People in a High-CO2 World: Where Can Science Make a Difference to People?

Author

Pendleton L, Comte A, Langdon C, Ekstrom JA, Cooley SR, Suatoni L, Beck MW, Brander LM, Burke L, Cinner JE, Doherty C, Edwards PE, Gledhill D, Jiang LQ, van Hooidonk RJ, Teh L, Waldbusser GG, and Ritter J

Subjects
Animals, Climate Change, Conservation of Natural Resources methods, Ecosystem, Geography, Global Warming, Humans, Hydrogen-Ion Concentration, Marine Biology methods, Models, Theoretical, Oceans and Seas, Seawater chemistry, Temperature, Anthozoa physiology, Carbon Dioxide metabolism, Coral Reefs, Fisheries
Abstract

Reefs and People at Risk: Increasing levels of carbon dioxide in the atmosphere put shallow, warm-water coral reef ecosystems, and the people who depend upon them at risk from two key global environmental stresses: 1) elevated sea surface temperature (that can cause coral bleaching and related mortality), and 2) ocean acidification. These global stressors: cannot be avoided by local management, compound local stressors, and hasten the loss of ecosystem services. Impacts to people will be most grave where a) human dependence on coral reef ecosystems is high, b) sea surface temperature reaches critical levels soonest, and c) ocean acidification levels are most severe. Where these elements align, swift action will be needed to protect people's lives and livelihoods, but such action must be informed by data and science., An Indicator Approach: Designing policies to offset potential harm to coral reef ecosystems and people requires a better understanding of where CO2-related global environmental stresses could cause the most severe impacts. Mapping indicators has been proposed as a way of combining natural and social science data to identify policy actions even when the needed science is relatively nascent. To identify where people are at risk and where more science is needed, we map indicators of biological, physical and social science factors to understand how human dependence on coral reef ecosystems will be affected by globally-driven threats to corals expected in a high-CO2 world. Western Mexico, Micronesia, Indonesia and parts of Australia have high human dependence and will likely face severe combined threats. As a region, Southeast Asia is particularly at risk. Many of the countries most dependent upon coral reef ecosystems are places for which we have the least robust data on ocean acidification. These areas require new data and interdisciplinary scientific research to help coral reef-dependent human communities better prepare for a high CO2 world., Competing Interests: The authors have declared that no competing interests exist.

Published
2016
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