Your search keyword '"Carbonate chemistry"' showing total 10 results

1. Oyster reefs' control of carbonate chemistry—Implications for oyster reef restoration in estuaries subject to coastal ocean acidification.

Author

Tomasetti, Stephen J., Doall, Michael H., Hallinan, Brendan D., Kraemer, Jeffrey R., and Gobler, Christopher J.

Subjects

*ESTUARINE restoration, *CORAL reef conservation, *OCEAN acidification, *REEFS, *OYSTERS, *HYDROGEN-ion concentration

Abstract

Globally, oyster reef restoration is one of the most widely applied coastal restoration interventions. While reefs are focal points of processes tightly linked to the carbonate system such as shell formation and respiration, how these processes alter reef carbonate chemistry relative to the surrounding seawater is unclear. Moreover, coastal systems are increasingly impacted by coastal acidification, which may affect reef carbonate chemistry. Here, we characterized the growth of multiple constructed reefs as well as summer variations in pH and carbonate chemistry of reef‐influenced seawater (in the middle of reefs) and ambient seawater (at locations ~50 m outside of reefs) to determine how reef chemistry was altered by the reef community and, in turn, impacts resident oysters. High frequency monitoring across three subtidal constructed reefs revealed reductions of daily mean and minimum pH (by 0.05–0.07 and 0.07–0.12 units, respectively) in seawater overlying reefs relative to ambient seawater (p <.0001). The proportion of pH measurements below 7.5, a threshold shown to negatively impact post‐larval oysters, were 1.8×–5.2× higher in reef seawater relative to ambient seawater. Most reef seawater samples (83%) were reduced in total alkalinity relative to ambient seawater samples, suggesting community calcification was a key driver of modified carbonate chemistry. The net metabolic influence of the reef community resulted in reductions of CaCO3 saturation state in 78% of discrete samples, and juvenile oysters placed on reefs exhibited slower shell growth (p <.05) compared to oysters placed outside of reefs. While differences in survival were not detected, reef oysters may benefit from enhanced survival or recruitment at the cost of slowed growth rates. Nevertheless, subtidal restored reef communities modified seawater carbonate chemistry in ways that likely increased oyster vulnerability to acidification, suggesting that carbonate chemistry dynamics warrant consideration when determining site suitability for oyster restoration, particularly under continued climate change. [ABSTRACT FROM AUTHOR]

Published

2023

2. Coast-wide evidence of low pH amelioration by seagrass ecosystems.

Author

Ricart, Aurora M, Ward, Melissa, Hill, Tessa M, Sanford, Eric, Kroeker, Kristy J, Takeshita, Yuichiro, Merolla, Sarah, Shukla, Priya, Ninokawa, Aaron T, Elsmore, Kristen, and Gaylord, Brian

Subjects

Zosteraceae, Carbon, Ecosystem, Seawater, Hydrogen-Ion Concentration, Zostera marina, buffer, carbon cycling, carbonate chemistry, mitigation, ocean acidification, photosynthesis, submerged aquatic vegetation, Zostera marina, Life Below Water, Environmental Sciences, Biological Sciences, Ecology

Abstract

Global-scale ocean acidification has spurred interest in the capacity of seagrass ecosystems to increase seawater pH within crucial shoreline habitats through photosynthetic activity. However, the dynamic variability of the coastal carbonate system has impeded generalization into whether seagrass aerobic metabolism ameliorates low pH on physiologically and ecologically relevant timescales. Here we present results of the most extensive study to date of pH modulation by seagrasses, spanning seven meadows (Zostera marina) and 1000 km of U.S. west coast over 6 years. Amelioration by seagrass ecosystems compared to non-vegetated areas occurred 65% of the time (mean increase 0.07 ± 0.008 SE). Events of continuous elevation in pH within seagrass ecosystems, indicating amelioration of low pH, were longer and of greater magnitude than opposing cases of reduced pH or exacerbation. Sustained elevations in pH of >0.1, comparable to a 30% decrease in [H+ ], were not restricted only to daylight hours but instead persisted for up to 21 days. Maximal pH elevations occurred in spring and summer during the seagrass growth season, with a tendency for stronger effects in higher latitude meadows. These results indicate that seagrass meadows can locally alleviate low pH conditions for extended periods of time with important implications for the conservation and management of coastal ecosystems.

Published

2021

3. The influences of diurnal variability and ocean acidification on the bioerosion rates of two reef‐dwelling Caribbean sponges.

Author

Morris, John, Enochs, Ian, Webb, Alice, de Bakker, Didier, Soderberg, Nash, Kolodziej, Graham, and Manzello, Derek

Subjects

*OCEAN acidification, *EROSION, *CORAL reefs & islands, *PHOTOSYNTHETIC rates, *CORALS, *MARINE organisms

Abstract

Ocean acidification (OA) is expected to modify the structure and function of coral reef ecosystems by reducing calcification, increasing bioerosion, and altering the physiology of many marine organisms. Much of our understanding of these relationships is based on experiments with static OA treatments, although evidence suggests that the magnitude of diurnal fluctuations in carbonate chemistry may modulate the calcification response to OA. These light‐mediated swings in seawater pH are projected to become more extreme with OA, yet their impact on bioerosion remains unknown. We evaluated the influence of diurnal carbonate chemistry variability on the bioerosion rates of two Caribbean sponges: the zooxanthellate Cliona varians and azooxanthellate Cliothosa delitrix. Replicate fragments from multiple colonies of each species were exposed to four precisely controlled pH treatments: contemporary static (8.05 ± 0.00; mean pH ± diurnal pH oscillation), contemporary variable (8.05 ± 0.10), future OA static (7.80 ± 0.00), and future OA variable (7.80 ± 0.10). Significantly enhanced bioerosion rates, determined using buoyant weight measurements, were observed under more variable conditions in both the contemporary and future OA scenarios for C. varians, whereas the same effect was only apparent under contemporary pH conditions for C. delitrix. These results indicate that variable carbonate chemistry has a stimulating influence on sponge bioerosion, and we hypothesize that bioerosion rates evolve non‐linearly as a function of pCO2 resulting in different magnitudes and directions of rate enhancement/reduction between day and night, even with an equal fluctuation around the mean. This response appeared to be intensified by photosymbionts, evident by the consistently higher percent increase in bioerosion rates for photosynthetic C. varians across all treatments. These findings further suggest that more variable natural ecosystems may presently experience elevated sponge bioerosion rates and that the heightened impact of OA enhanced bioerosion on reef habitat could occur sooner than prior predictions. [ABSTRACT FROM AUTHOR]

Published

2022

4. Characterizing biogeochemical fluctuations in a world of extremes: A synthesis for temperate intertidal habitats in the face of global change.

Author

Wolfe, Kennedy, Nguyen, Hong D., Davey, Madeline, and Byrne, Maria

Subjects

*INTERTIDAL ecology, *HABITATS, *BIOTIC communities, *WATER sampling, *CLIMATE extremes, *CLIMATE change, *CIRCADIAN rhythms

Abstract

Coastal and intertidal habitats are at the forefront of anthropogenic influence and environmental change. The species occupying these habitats are adapted to a world of extremes, which may render them robust to the changing climate or more vulnerable if they are at their physiological limits. We characterized the diurnal, seasonal and interannual patterns of flux in biogeochemistry across an intertidal gradient on a temperate sandstone platform in eastern Australia over 6 years (2009–2015) and present a synthesis of our current understanding of this habitat in context with global change. We used rock pools as natural mesocosms to determine biogeochemistry dynamics and patterns of eco‐stress experienced by resident biota. In situ measurements and discrete water samples were collected night and day during neap low tide events to capture diurnal biogeochemistry cycles. Calculation of pHT using total alkalinity (TA) and dissolved inorganic carbon (DIC) revealed that the mid‐intertidal habitat exhibited the greatest flux over the years (pHT 7.52–8.87), and over a single tidal cycle (1.11 pHT units), while the low‐intertidal (pHT 7.82–8.30) and subtidal (pHT 7.87–8.30) were less variable. Temperature flux was also greatest in the mid‐intertidal (8.0–34.5°C) and over a single tidal event (14°C range), as typical of temperate rocky shores. Mean TA and DIC increased at night and decreased during the day, with the most extreme conditions measured in the mid‐intertidal owing to prolonged emersion periods. Temporal sampling revealed that net ecosystem calcification and production were highest during the day and lowest at night, particularly in the mid‐intertidal. Characterization of biogeochemical fluctuations in a world of extremes demonstrates the variable conditions that intertidal biota routinely experience and highlight potential microhabitat‐specific vulnerabilities and climate change refugia. [ABSTRACT FROM AUTHOR]

Published

2020

5. Environmental and physiochemical controls on coral calcification along a latitudinal temperature gradient in Western Australia.

Author

Ross, Claire L., DeCarlo, Thomas M., and McCulloch, Malcolm T.

Subjects

*CALCIFICATION, *CORALS, *BORON isotopes, *RAMAN spectroscopy, *GLOBAL warming

Abstract

The processes that occur at the micro‐scale site of calcification are fundamental to understanding the response of coral growth in a changing world. However, our mechanistic understanding of chemical processes driving calcification is still evolving. Here, we report the results of a long‐term in situ study of coral calcification rates, photo‐physiology, and calcifying fluid (cf) carbonate chemistry (using boron isotopes, elemental systematics, and Raman spectroscopy) for seven species (four genera) of symbiotic corals growing in their natural environments at tropical, subtropical, and temperate locations in Western Australia (latitudinal range of ~11°). We find that changes in net coral calcification rates are primarily driven by pHcf and carbonate ion concentration [CO32−]cf in conjunction with temperature and DICcf. Coral pHcf varies with latitudinal and seasonal changes in temperature and works together with the seasonally varying DICcf to optimize [CO32−]cf at species‐dependent levels. Our results indicate that corals shift their pHcf to adapt and/or acclimatize to their localized thermal regimes. This biological response is likely to have critical implications for predicting the future of coral reefs under CO2‐driven warming and acidification. We report in situ changes in coral calcification rates, photo‐physiology, and calcifying fluid (cf) carbonate chemistry (using boron isotopes, elemental systematics, and Raman spectroscopy) for corals growing in their natural environments at tropical, subtropical, and temperate locations in Western Australia. We find that changes in coral calcification rates are primarily driven by pHcf and carbonate ion concentration in conjunction with temperature and DICcf. Our results further indicate that corals shift their pHcf to adjust to their localized thermal regimes. This biological response is likely to have critical implications for determining the future of coral reefs under CO2‐driven warming and acidification. [ABSTRACT FROM AUTHOR]

Published

2019

6. Geographical CO2 sensitivity of phytoplankton correlates with ocean buffer capacity.

Author

Richier, Sophie, Achterberg, Eric P., Humphreys, Matthew P., Poulton, Alex J., Suggett, David J., Tyrrell, Toby, and Moore, Christopher Mark

Subjects

*PHYTOPLANKTON, *PHOTOSYNTHESIS, *MARINE ecology, *OCEAN acidification, *CLIMATE change

Abstract

Abstract: Accumulation of anthropogenic CO2 is significantly altering ocean chemistry. A range of biological impacts resulting from this oceanic CO2 accumulation are emerging, however, the mechanisms responsible for observed differential susceptibility between organisms and across environmental settings remain obscure. A primary consequence of increased oceanic CO2 uptake is a decrease in the carbonate system buffer capacity, which characterizes the system's chemical resilience to changes in CO2, generating the potential for enhanced variability in pCO2 and the concentration of carbonate [ CO 3 2 −], bicarbonate [ HCO 3 −], and protons [H+] in the future ocean. We conducted a meta‐analysis of 17 shipboard manipulation experiments performed across three distinct geographical regions that encompassed a wide range of environmental conditions from European temperate seas to Arctic and Southern oceans. These data demonstrated a correlation between the magnitude of natural phytoplankton community biological responses to short‐term CO2 changes and variability in the local buffer capacity across ocean basin scales. Specifically, short‐term suppression of small phytoplankton (<10 μm) net growth rates were consistently observed under enhanced pCO2 within experiments performed in regions with higher ambient buffer capacity. The results further highlight the relevance of phytoplankton cell size for the impacts of enhanced pCO2 in both the modern and future ocean. Specifically, cell size‐related acclimation and adaptation to regional environmental variability, as characterized by buffer capacity, likely influences interactions between primary producers and carbonate chemistry over a range of spatio‐temporal scales. [ABSTRACT FROM AUTHOR]

Published

2018

7. Coast‐wide evidence of low pH amelioration by seagrass ecosystems

Author

Brian Gaylord, Priya Shukla, Eric Sanford, Kristen Elsmore, Aurora M. Ricart, Melissa Ward, Tessa M. Hill, Sarah Merolla, Yuichiro Takeshita, Aaron Ninokawa, and Kristy J. Kroeker

Subjects

0106 biological sciences, 010504 meteorology & atmospheric sciences, ocean acidification, carbon cycling, 010603 evolutionary biology, 01 natural sciences, Latitude, Carbon cycle, mitigation, Environmental Chemistry, Primary Research Article, Seawater, Ecosystem, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, photosynthesis, Ecology, biology, Zosteraceae, carbonate chemistry, Ocean acidification, Zostera marina, Hydrogen-Ion Concentration, Primary Research Articles, biology.organism_classification, Carbon, Seagrass, Habitat, Environmental science, submerged aquatic vegetation, buffer

Abstract

Global‐scale ocean acidification has spurred interest in the capacity of seagrass ecosystems to increase seawater pH within crucial shoreline habitats through photosynthetic activity. However, the dynamic variability of the coastal carbonate system has impeded generalization into whether seagrass aerobic metabolism ameliorates low pH on physiologically and ecologically relevant timescales. Here we present results of the most extensive study to date of pH modulation by seagrasses, spanning seven meadows (Zostera marina) and 1000 km of U.S. west coast over 6 years. Amelioration by seagrass ecosystems compared to non‐vegetated areas occurred 65% of the time (mean increase 0.07 ± 0.008 SE). Events of continuous elevation in pH within seagrass ecosystems, indicating amelioration of low pH, were longer and of greater magnitude than opposing cases of reduced pH or exacerbation. Sustained elevations in pH of >0.1, comparable to a 30% decrease in [H+], were not restricted only to daylight hours but instead persisted for up to 21 days. Maximal pH elevations occurred in spring and summer during the seagrass growth season, with a tendency for stronger effects in higher latitude meadows. These results indicate that seagrass meadows can locally alleviate low pH conditions for extended periods of time with important implications for the conservation and management of coastal ecosystems., The most extensive study to date of pH modulation by seagrasses, spanning seven meadows (Zostera marina) and 1000 km of U.S. west coast over 6 years. Amelioration of low pH by seagrass ecosystems occurred most of the time, where events of continuous elevation in pH were longer and of greater magnitude than opposing cases of reduced pH or exacerbation. Sustained elevations in pH were not restricted only to daylight hours. Maximal pH elevations occurred in spring and summer during the seagrass growth season, with a tendency for stronger effects in higher latitude meadows.

Published

2021

8. Impacts of ocean acidification on marine organisms: quantifying sensitivities and interaction with warming.

Author

Kroeker, Kristy J., Kordas, Rebecca L., Crim, Ryan, Hendriks, Iris E., Ramajo, Laura, Singh, Gerald S., Duarte, Carlos M., and Gattuso, Jean‐Pierre

Subjects

*OCEAN acidification, *MARINE organisms, *ECOLOGICAL impact, *OCEAN temperature, *CLIMATE change, *MARINE ecology

Abstract

Ocean acidification represents a threat to marine species worldwide, and forecasting the ecological impacts of acidification is a high priority for science, management, and policy. As research on the topic expands at an exponential rate, a comprehensive understanding of the variability in organisms' responses and corresponding levels of certainty is necessary to forecast the ecological effects. Here, we perform the most comprehensive meta-analysis to date by synthesizing the results of 228 studies examining biological responses to ocean acidification. The results reveal decreased survival, calcification, growth, development and abundance in response to acidification when the broad range of marine organisms is pooled together. However, the magnitude of these responses varies among taxonomic groups, suggesting there is some predictable trait-based variation in sensitivity, despite the investigation of approximately 100 new species in recent research. The results also reveal an enhanced sensitivity of mollusk larvae, but suggest that an enhanced sensitivity of early life history stages is not universal across all taxonomic groups. In addition, the variability in species' responses is enhanced when they are exposed to acidification in multi-species assemblages, suggesting that it is important to consider indirect effects and exercise caution when forecasting abundance patterns from single-species laboratory experiments. Furthermore, the results suggest that other factors, such as nutritional status or source population, could cause substantial variation in organisms' responses. Last, the results highlight a trend towards enhanced sensitivity to acidification when taxa are concurrently exposed to elevated seawater temperature. [ABSTRACT FROM AUTHOR]

Published

2013

9. Sensitivity of coral calcification to ocean acidification: a meta-analysis.

Author

Chan, Neil C. S. and Connolly, Sean R.

Subjects

*CALCIFICATION, *CORALS, *OCEAN acidification, *CARBONATES, *GLOBAL environmental change, *BIOLOGY

Abstract

To date, meta-analyses of effects of acidification have focused on the overall strength of evidence for statistically significant responses; however, to anticipate likely consequences of ocean acidification, quantitative estimates of the magnitude of likely responses are also needed. Herein, we use random effects meta-analysis to produce a systematically integrated measure of the distribution of magnitudes of the response of coral calcification to decreasing ΩArag. We also tested whether methodological and biological factors that have been hypothesized to drive variation in response magnitude explain a significant proportion of the among-study variation. We found that the overall mean response of coral calcification is ~15% per unit decrease in ΩArag over the range 2 < ΩArag < 4. Among-study variation is large (standard deviation of 8% per unit decrease in ΩArag). Neither differences in carbonate chemistry manipulation method, study duration, irradiance level, nor study species growth rate explained a significant proportion of the among-study variation. However, studies employing buoyant weighting found significantly smaller decreases in calcification per unit ΩArag (~10%), compared with studies using the alkalinity anomaly technique (~25%). These differences may be due to the greater tendency for the former to integrate over light and dark calcification. If the existing body of experimental work is indeed representative of likely responses of corals in nature, our results imply that, under business as usual conditions, declines in coral calcification by end-of-century will be ~22%, on average, or ~15% if only studies integrating light and dark calcification are considered. These values are near the low end of published projections, but support the emerging view that variability due to local environmental conditions and species composition is likely to be substantial. [ABSTRACT FROM AUTHOR]

Published

2013

10. Geographical CO 2 sensitivity of phytoplankton correlates with ocean buffer capacity.

Author

Richier S, Achterberg EP, Humphreys MP, Poulton AJ, Suggett DJ, Tyrrell T, and Moore CM

Subjects

Acclimatization, Carbonates, Geography, Oceans and Seas, Carbon Dioxide analysis, Climate, Phytoplankton physiology, Seawater chemistry

Abstract

Accumulation of anthropogenic CO 2 is significantly altering ocean chemistry. A range of biological impacts resulting from this oceanic CO 2 accumulation are emerging, however, the mechanisms responsible for observed differential susceptibility between organisms and across environmental settings remain obscure. A primary consequence of increased oceanic CO 2 uptake is a decrease in the carbonate system buffer capacity, which characterizes the system's chemical resilience to changes in CO 2 , generating the potential for enhanced variability in pCO 2 and the concentration of carbonate [ CO 3 2 - ], bicarbonate [ HCO 3 - ], and protons [H + ] in the future ocean. We conducted a meta-analysis of 17 shipboard manipulation experiments performed across three distinct geographical regions that encompassed a wide range of environmental conditions from European temperate seas to Arctic and Southern oceans. These data demonstrated a correlation between the magnitude of natural phytoplankton community biological responses to short-term CO 2 changes and variability in the local buffer capacity across ocean basin scales. Specifically, short-term suppression of small phytoplankton (<10 μm) net growth rates were consistently observed under enhanced pCO 2 within experiments performed in regions with higher ambient buffer capacity. The results further highlight the relevance of phytoplankton cell size for the impacts of enhanced pCO 2 in both the modern and future ocean. Specifically, cell size-related acclimation and adaptation to regional environmental variability, as characterized by buffer capacity, likely influences interactions between primary producers and carbonate chemistry over a range of spatio-temporal scales., (© 2018 John Wiley & Sons Ltd.)

Published

2018