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  • 1
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    Secondary calcification and dissolution respond differently to future ocean conditions (2015)
    PANGAEA
    In:  Supplement to: Silbiger, N J; Donahue, M J (2015): Secondary calcification and dissolution respond differently to future ocean conditions. Biogeosciences, 12(2), 567-578, https://doi.org/10.5194/bg-12-567-2015
    Details
    Publication Date: 2024-03-15
    Description: Climate change threatens both the accretion and erosion processes that sustain coral reefs. Secondary calcification, bioerosion, and reef dissolution are integral to the structural complexity and long-term persistence of coral reefs, yet these processes have received less research attention than reef accretion by corals. In this study, we use climate scenarios from RCP 8.5 to examine the combined effects of rising ocean acidity and sea surface temperature (SST) on both secondary calcification and dissolution rates of a natural coral rubble community using a flow-through aquarium system. We found that secondary reef calcification and dissolution responded differently to the combined effect of pCO2 and temperature. Calcification had a non-linear response to the combined effect of pCO2 and temperature: the highest calcification rate occurred slightly above ambient conditions and the lowest calcification rate was in the highest temperature-pCO2 condition. In contrast, dissolution increased linearly with temperature-pCO2 . The rubble community switched from net calcification to net dissolution at +271 µatm pCO2 and 0.75 °C above ambient conditions, suggesting that rubble reefs may shift from net calcification to net dissolution before the end of the century. Our results indicate that (i) dissolution may be more sensitive to climate change than calcification and (ii) that calcification and dissolution have different functional responses to climate stressors; this highlights the need to study the effects of climate stressors on both calcification and dissolution to predict future changes in coral reefs.
    Keywords: Alkalinity, total; Alkalinity, total, standard error; Ammonium; Ammonium, standard error; Aragonite saturation state; Aragonite saturation state, standard error; Benthos; Bicarbonate ion; Bicarbonate ion, standard error; Calcification/Dissolution; Calcification rate of calcium carbonate; Calcite saturation state; Calculated using CO2SYS; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbon, inorganic, dissolved, standard error; Carbonate ion; Carbonate ion, standard error; Carbonate system computation flag; Carbon dioxide; Coast and continental shelf; Coconut_Island; Containers and aquaria (20-1000 L or 〈 1 m**2); Entire community; EXP; Experiment; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Laboratory experiment; Net calcification rate of calcium carbonate; Net community production of carbon; Nitrate; Nitrate, standard error; Nitrite; Nitrite, standard error; North Pacific; OA-ICC; Ocean Acidification International Coordination Centre; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); Partial pressure of carbon dioxide (water) at sea surface temperature (wet air), standard error; pH; pH, standard error; Phosphate; Phosphate, standard error; Potentiometric titration; Primary production/Photosynthesis; Rocky-shore community; Salinity; Salinity, standard error; Silicate; Silicate, standard error; Spectrophotometric; Standardized climate change; Temperature; Temperature, water; Temperature, water, standard error; Treatment; Tropical
    Type: Dataset
    Format: text/tab-separated-values, 2952 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 2
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    Reefs shift from net accretion to net erosion along a natural environmental gradient (2014)
    PANGAEA
    In:  Supplement to: Silbiger, N J; Guadayol, Òscar; Thomas, Florence I M; Donahue, M J (2014): Reefs shift from net accretion to net erosion along a natural environmental gradient. Marine Ecology Progress Series, 515, 33-44, https://doi.org/10.3354/meps10999
    Details
    Publication Date: 2024-03-15
    Description: Coral reefs persist in an accretion-erosion balance and ocean acidification resulting from anthropogenic CO2 emissions threatens to shift this balance in favor of net reef erosion. Corals and calcifying algae, largely responsible for reef accretion, are vulnerable to environmental changes associated with ocean acidification, but the direct effects of lower pH on reef erosion has received less attention, particularly in the context of known drivers of bioerosion and natural variability. This study examines the balance between reef accretion and erosion along a well-characterized natural environmental gradient in Kane'ohe Bay, Hawai'i using experimental blocks of coral skeleton. Comparing before and after micro-computed tomography (µCT) scans to quantify net accretion and erosion, we show that, at the small spatial scale of this study (tens of meters), pH was a better predictor of the accretion-erosion balance than environmental drivers suggested by prior studies, including resource availability, temperature, distance from shore, or depth. In addition, this study highlights the fine-scale variation of pH in coastal systems and the importance of microhabitat variation for reef accretion and erosion processes. We demonstrate significant changes in both the mean and variance of pH on the order of meters, providing a local perspective on global increases in pCO2. Our findings suggest that increases in reef erosion, combined with expected decreases in calcification, will accelerate the shift of coral reefs to an erosion-dominated system in a high-CO2 world. This shift will make reefs increasingly susceptible to storm damage and sea-level rise, threatening the maintenance of the ecosystem services that coral reefs provide.
    Keywords: Alkalinity, total; Alkalinity, total, standard deviation; Aragonite saturation state; Benthos; Bicarbonate ion; Calcification/Dissolution; Calcite saturation state; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbon, inorganic, dissolved, standard deviation; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Change; Chlorophyll a; Chlorophyll a, standard deviation; Coast and continental shelf; Coconut_Island; DEPTH, water; Distance; Entire community; EXP; Experiment; Field observation; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Nitrogen/Phosphorus ratio; Nitrogen/Phosphorus ratio, standard deviation; North Atlantic; OA-ICC; Ocean Acidification International Coordination Centre; Partial pressure of carbon dioxide, standard deviation; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); pH; pH, standard deviation; Potentiometric titration; Rocky-shore community; Salinity; Salinity, standard deviation; Spectrophotometric; Temperature, water; Temperature, water, standard deviation; Temperature anomaly; Tropical
    Type: Dataset
    Format: text/tab-separated-values, 580 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 3
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    Seawater carbonate chemistry and net community production and net ecosystem calcification in tide pools (2018)
    PANGAEA
    Details
    Publication Date: 2024-03-15
    Description: Predicting the impacts of ocean acidification in coastal habitats is complicated by bio-physical feedbacks between organisms and carbonate chemistry. Daily changes in pH and other carbonate parameters in coastal ecosystems, associated with processes such as photosynthesis and respiration, often greatly exceed global mean predicted changes over the next century. We assessed the strength of these feedbacks under projected elevated CO2 levels by conducting a field experiment in 10 macrophyte-dominated tide pools on the coast of California, USA. We evaluated changes in carbonate parameters over time and found that under ambient conditions, daytime changes in pH, pCO2, net ecosystem calcification (NEC), and O2 concentrations were strongly related to rates of net community production (NCP). CO2 was added to pools during daytime low tides, which should have reduced pH and enhanced pCO2. However, photosynthesis rapidly reduced pCO2 and increased pH, so effects of CO2 addition were not apparent unless we accounted for seaweed and surfgrass abundances. In the absence of macrophytes, CO2 addition caused pH to decline by ∼0.6 units and pCO2 to increase by ∼487 µatm over 6 hr during the daytime low tide. As macrophyte abundances increased, the impacts of CO2 addition declined because more CO2 was absorbed due to photosynthesis. Effects of CO2addition were, therefore, modified by feedbacks between NCP, pH, pCO2, and NEC. Our results underscore the potential importance of coastal macrophytes in ameliorating impacts of ocean acidification.
    Keywords: Alkalinity, total; Ammonium; Aragonite saturation state; Area; Bicarbonate ion; Calcite saturation state; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Carbon dioxide, air-sea, flux; Coverage; Day of experiment; Difference; EXP; Experiment; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Horseshoe_Cove_OA; Identification; Irradiance; Net calcification rate of calcium carbonate; Net community production, dissolved inorganic carbon; Nitrate and Nitrite; Oxygen, dissolved; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); pH; Phosphate; Salinity; Surface area; Temperature, water; Time in hours; Treatment; Type; Volume; Wind speed; Δ alkalinity, total
    Type: Dataset
    Format: text/tab-separated-values, 1100 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 4
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    Seawater carbonate chemistry and net community production and net ecosystem calcification in tide pools (2018)
    PANGAEA
    Details
    Publication Date: 2024-03-15
    Description: Predicting the impacts of ocean acidification in coastal habitats is complicated by bio-physical feedbacks between organisms and carbonate chemistry. Daily changes in pH and other carbonate parameters in coastal ecosystems, associated with processes such as photosynthesis and respiration, often greatly exceed global mean predicted changes over the next century. We assessed the strength of these feedbacks under projected elevated CO2 levels by conducting a field experiment in 10 macrophyte-dominated tide pools on the coast of California, USA. We evaluated changes in carbonate parameters over time and found that under ambient conditions, daytime changes in pH, pCO2, net ecosystem calcification (NEC), and O2 concentrations were strongly related to rates of net community production (NCP). CO2 was added to pools during daytime low tides, which should have reduced pH and enhanced pCO2. However, photosynthesis rapidly reduced pCO2 and increased pH, so effects of CO2 addition were not apparent unless we accounted for seaweed and surfgrass abundances. In the absence of macrophytes, CO2 addition caused pH to decline by ∼0.6 units and pCO2 to increase by ∼487 µatm over 6 hr during the daytime low tide. As macrophyte abundances increased, the impacts of CO2 addition declined because more CO2 was absorbed due to photosynthesis. Effects of CO2addition were, therefore, modified by feedbacks between NCP, pH, pCO2, and NEC. Our results underscore the potential importance of coastal macrophytes in ameliorating impacts of ocean acidification.
    Keywords: Alkalinity, total; Ammonium; Aragonite saturation state; Area; Benthos; Bicarbonate ion; Calcification/Dissolution; Calcite saturation state; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Carbon dioxide, air-sea, flux; Coast and continental shelf; Community composition and diversity; Containers and aquaria (20-1000 L or 〈 1 m**2); Coverage; Day of experiment; Difference; Entire community; EXP; Experiment; Field experiment; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Horseshoe_Cove_OA; Identification; Irradiance; Net calcification rate of calcium carbonate; Net community production, dissolved inorganic carbon; Nitrate and Nitrite; North Pacific; OA-ICC; Ocean Acidification International Coordination Centre; Oxygen, dissolved; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); pH; Phosphate; Primary production/Photosynthesis; Rocky-shore community; Salinity; Surface area; Temperate; Temperature, water; Time in hours; Treatment; Type; Volume; Wind speed; Δ alkalinity, total
    Type: Dataset
    Format: text/tab-separated-values, 1100 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 5
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    Seawater carbonate chemistry and net community calcification (NCC) and net community production (NCP) rates of individual taxa and combined reef communities (2018)
    PANGAEA
    Details
    Publication Date: 2024-03-15
    Description: There is a long history of examining the impacts of nutrient pollution and pH on coral reefs. However, little is known about how these two stressors interact and influence coral reef ecosystem functioning. Using a six-week nutrient addition experiment, we measured the impact of elevated nitrate (NO−3) and phosphate (PO3−4) on net community calcification (NCC) and net community production (NCP) rates of individual taxa and combined reef communities. Our study had four major outcomes: (i) NCC rates declined in response to nutrient addition in all substrate types, (ii) the mixed community switched from net calcification to net dissolution under medium and high nutrient conditions, (iii) nutrients augmented pH variability through modified photosynthesis and respiration rates, and (iv) nutrients disrupted the relationship between NCC and aragonite saturation state documented in ambient conditions. These results indicate that the negative effect of NO−3 and PO3−4 addition on reef calcification is likely both a direct physiological response to nutrients and also an indirect response to a shifting pH environment from altered NCP rates. Here, we show that nutrient pollution could make reefs more vulnerable to global changes associated with ocean acidification and accelerate the predicted shift from net accretion to net erosion.
    Keywords: Alkalinity, total; Animalia; Aquarium number; Aragonite saturation state; Ash free dry mass; Benthos; Bicarbonate ion; Bottles or small containers/Aquaria (〈20 L); Calcification/Dissolution; Calcite saturation state; Calculated using seacarb; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate system computation flag; Carbon dioxide; Cnidaria; Coast and continental shelf; Coconut_Island; DATE/TIME; Dry mass; Entire community; EXP; Experiment; Flow rate; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Gracillaria salicornia; Gross primary production of oxygen; Identification; Laboratory experiment; Light mode; Macroalgae; Macro-nutrients; Montipora capitata; Net calcification rate of calcium carbonate; Net primary production of oxygen; Nitrate and Nitrite; North Pacific; OA-ICC; Ocean Acidification International Coordination Centre; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); pH; Phosphate; Plantae; Porites compressa; Potentiometric; Potentiometric titration; Primary production/Photosynthesis; Residence time; Respiration rate, oxygen; Rhodophyta; Rocky-shore community; Salinity; Silicate; Single species; Substrate type; Surface area; Temperature, water; Treatment; Tropical; Type; Volume
    Type: Dataset
    Format: text/tab-separated-values, 27720 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 6
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    Impact of high pCO2 and warmer temperatures on the process of silica biomineralization in the sponge Mycale grandis (2016)
    PANGAEA
    In:  Supplement to: Vicente, Jan; Silbiger, N J; Beckley, Billie A; Raczkowski, Charles W; Hill, R (2016): Impact of high pCO2 and warmer temperatures on the process of silica biomineralization in the sponge Mycale grandis. ICES Journal of Marine Science, 73(3), 704-714, https://doi.org/10.1093/icesjms/fsv235
    Details
    Publication Date: 2024-03-15
    Description: Siliceous sponges have survived pre-historical mass extinction events caused by ocean acidification and recent studies suggest that siliceous sponges will continue to resist predicted increases in ocean acidity. In this study, we monitored silica biomineralization in the Hawaiian sponge Mycale grandis under predicted pCO2 and sea surface temperature scenarios for 2100. Our goal was to determine if spicule biomineralization was enhanced or repressed by ocean acidification and thermal stress by monitoring silica uptake rates during short-term (48 h) experiments and comparing biomineralized tissue ratios before and after a long-term (26 d) experiment. In the short-term experiment, we found that silica uptake rates were not impacted by high pCO2 (1050 µatm), warmer temperatures (27°C), or combined high pCO2 with warmer temperature (1119 µatm; 27°C) treatments. The long-term exposure experiments revealed no effect on survival or growth rates of M. grandis to high pCO2 (1198 µatm), warmer temperatures (25.6°C), or combined high pCO2 with warmer temperature (1225 µatm, 25.7°C) treatments, indicating that M. grandis will continue to prosper under predicted increases in pCO2 and sea surface temperature. However, ash-free dry weight to dry weight ratios, subtylostyle lengths, and silicified weight to dry weight ratios decreased under conditions of high pCO2 and combined pCO2 warmer temperature treatments. Our results show that rising ocean acidity and temperature have marginal negative effects on spicule biomineralization and will not affect sponge survival rates of M. grandis.
    Keywords: Alkalinity, total; Alkalinity, total, standard error; Animalia; Aragonite saturation state; Aragonite saturation state, standard error; Benthic animals; Benthos; Bicarbonate ion; Bicarbonate ion, standard error; Biomass, ash free dry mass; Bottles or small containers/Aquaria (〈20 L); Calcite saturation state; Calculated using CO2SYS; Calculated using seacarb after Nisumaa et al. (2010); Carbon, inorganic, dissolved; Carbonate ion; Carbonate ion, standard error; Carbonate system computation flag; Carbon dioxide; Coast and continental shelf; Figure; Fugacity of carbon dioxide (water) at sea surface temperature (wet air); Growth/Morphology; Identification; Laboratory experiment; Length; Mycale grandis; North Pacific; OA-ICC; Ocean Acidification International Coordination Centre; Other metabolic rates; Oxygen; Oxygen, standard error; Partial pressure of carbon dioxide (water) at sea surface temperature (wet air); Partial pressure of carbon dioxide (water) at sea surface temperature (wet air), standard error; pH; pH, standard error; Porifera; Potentiometric; Potentiometric titration; Ratio; Registration number of species; Replicate; Salinity; Salinity, standard error; Sample ID; Silicate; Silicate, standard error; Silicate uptake rate; Single species; Species; Temperature; Temperature, water; Temperature, water, standard error; Time in hours; Treatment; Tropical; Type; Uniform resource locator/link to reference; Weight loss; Width
    Type: Dataset
    Format: text/tab-separated-values, 81732 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 7
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    Impact of high pCO2 and warmer temperatures on the process of silica biomineralization in the sponge Mycale grandis (2016)
    Oxford University Press
    Details
    Publication Date: 2016-02-27
    Description: Siliceous sponges have survived pre-historical mass extinction events caused by ocean acidification and recent studies suggest that siliceous sponges will continue to resist predicted increases in ocean acidity. In this study, we monitored silica biomineralization in the Hawaiian sponge Mycale grandis under predicted p CO 2 and sea surface temperature scenarios for 2100. Our goal was to determine if spicule biomineralization was enhanced or repressed by ocean acidification and thermal stress by monitoring silica uptake rates during short-term (48 h) experiments and comparing biomineralized tissue ratios before and after a long-term (26 d) experiment. In the short-term experiment, we found that silica uptake rates were not impacted by high p CO 2 (1050 µatm), warmer temperatures (27°C), or combined high p CO 2 with warmer temperature (1119 µatm; 27°C) treatments. The long-term exposure experiments revealed no effect on survival or growth rates of M. grandis to high p CO 2 (1198 µatm), warmer temperatures (25.6°C), or combined high p CO 2 with warmer temperature (1225 µatm, 25.7°C) treatments, indicating that M. grandis will continue to prosper under predicted increases in p CO 2 and sea surface temperature. However, ash-free dry weight to dry weight ratios, subtylostyle lengths, and silicified weight to dry weight ratios decreased under conditions of high p CO 2 and combined p CO 2 warmer temperature treatments. Our results show that rising ocean acidity and temperature have marginal negative effects on spicule biomineralization and will not affect sponge survival rates of M. grandis .
    Print ISSN: 1054-3139
    Electronic ISSN: 1095-9289
    Topics: Biology , Geosciences , Physics
    Published by Oxford University Press
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