Search results for " acidification"

showing 10 items of 155 documents

Effects of ocean acidification on the shells of four Mediterranean gastropod species near a CO2 seep

2017

Marine CO2seeps allow the study of the long-term effects of elevated pCO2(ocean acidification) on marine invertebrate biomineralization. We investigated the effects of ocean acidification on shell composition and structure in four ecologically important species of Mediterranean gastropods (two limpets, a top-shell snail, and a whelk). Individuals were sampled from three sites near a volcanic CO2seep off Vulcano Island, Italy. The three sites represented ambient (8.15 pH), moderate (8.03 pH) and low (7.73 pH) seawater mean pH. Shell mineralogy, microstructure, and mechanical strength were examined in all four species. We found that the calcite/aragonite ratio could vary and increased signifi…

Settore BIO/07 - Ecologia0106 biological sciences010504 meteorology & atmospheric sciencesMediterraneanAquatic Scienceengineering.materialOceanography01 natural scienceschemistry.chemical_compoundWhelkCO2 seepShellGastropodMineral0105 earth and related environmental sciencesCalcitebiologyOcean acidification010604 marine biology & hydrobiologyLimpetAragoniteOcean acidificationMarine invertebratesbiology.organism_classificationPollutionPetroleum seepOceanographychemistryengineeringSeawaterGeologyMarine Pollution Bulletin
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Altered epiphyte community and sea urchin diet in Posidonia oceanica meadows in the vicinity of volcanic CO2 vents

2017

Ocean acidification (OA) predicted for 2100 is expected to shift seagrass epiphyte communities towards the dominance of more tolerant non-calcifying taxa. However, little is known about the indirect effects of such changes on food provision to key seagrass consumers. We found that epiphyte communities of the seagrass Posidonia oceanica in two naturally acidified sites (i.e. north and south sides of a volcanic CO2 vent) and in a control site away from the vent at the Ischia Island (NW Mediterranean Sea) significantly differed in composition and abundance. Such differences involved a higher abundance of non-calcareous crustose brown algae and a decline of calcifying polychaetes in both acidif…

Settore BIO/07 - Ecologia0106 biological sciencesAssemblagesPH reductionAlgalGrowthAquatic ScienceOceanography010603 evolutionary biology01 natural sciencesParacentrotus lividusAcidificationAlgaeParacentrotus-lividus lam.Seawater14. Life underwaterHerbivoryClimate-changebiologyEcology010604 marine biology & hydrobiologyCoralline algaeGeneral MedicineEcosystem shiftsbiology.organism_classificationPollutionSeagrass13. Climate actionPosidonia oceanicaEpiphyteCrustoseSeagrass meadowsCoastal waters Coralline algae Calcifying organisms Community composition Epiphytes Global change Gut content Marine ecology Ocean acidification Paracentrotus lividus Seagrass
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Ocean acidification as a driver of community simplification via the collapse of higher-order and rise of lower-order consumers

2017

AbstractIncreasing oceanic uptake of CO2 is predicted to drive ecological change as both a resource (i.e. CO2 enrichment on primary producers) and stressor (i.e. lower pH on consumers). We use the natural ecological complexity of a CO2 vent (i.e. a seagrass system) to assess the potential validity of conceptual models developed from laboratory and mesocosm research. Our observations suggest that the stressor-effect of CO2 enrichment combined with its resource-effect drives simplified food web structure of lower trophic diversity and shorter length. The transfer of CO2 enrichment from plants to herbivores through consumption (apparent resource-effect) was not compensated by predation, becaus…

Settore BIO/07 - Ecologia0106 biological sciencesHerbivoreMultidisciplinaryEnvironmental changePrimary producersEcologyScience010604 marine biology & hydrobiologyQROcean acidificationBiology010603 evolutionary biology01 natural sciencesArticleFood webPredationmacrozoobenthos CO2 vents top-down control bottom-up control13. Climate actionMedicineDominance (ecology)14. Life underwaterTrophic levelScientific Reports
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Ocean acidification can mediate biodiversity shifts by changing biogenic habitat

2016

The effects of ocean acidification (OA) on the structure and complexity of coastal marine biogenic habitat have been broadly overlooked. Here we explore how declining pH and carbonate saturation may affect the structural complexity of four major biogenic habitats. Our analyses predict that indirect effects driven by OA on habitat-forming organisms could lead to lower species diversity in coral reefs, mussel beds and some macroalgal habitats, but increases in seagrass and other macroalgal habitats. Available in situ data support the prediction of decreased biodiversity in coral reefs, but not the prediction of seagrass bed gains. Thus, OA-driven habitat loss may exacerbate the direct negativ…

Settore BIO/07 - Ecologia0106 biological sciencesgeographygeography.geographical_feature_category010504 meteorology & atmospheric sciencesbiologyEcology010604 marine biology & hydrobiologyfungiBiodiversityOcean acidificationCoral reefEnvironmental Science (miscellaneous)biology.organism_classification01 natural sciencesHabitat destructionSeagrassHabitatocean acidification biogenic habitat mussel bed macroalgae seagrass coral reefEnvironmental scienceEcosystemSpecies richnessSocial Sciences (miscellaneous)0105 earth and related environmental sciences
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ROLE OF BEHAVIOUR IN MARINE ORGANISMS: POTENTIAL EFFECTS UNDER FUTURE OCEAN CONDITIONS.

2021

Over the last 250 years, the intensive burning of fossil fuels along with industrial processes and land uses (e.g. clearing forests and agriculture) has contributed to an increase in atmospheric CO2 from approximately 280 to 410 ppm, with a further increase (from 730 to 1020 ppm) projected by the end of this century. About 30% of the anthropogenic CO2 has been absorbed by the ocean, with a consequent decrease of the ocean’s surface pH causing a phenomenon better known as Ocean Acidification (OA). The average pH of the surface ocean has declined from 8.2 by 0.1 units since pre-industrial times as a result of CO2 emissions and a further reduction of 0.3–0.5 pH units is expected to occur by th…

Settore BIO/07 - EcologiaBehavioural plasticity parental investment antipredator behaviour reproductive success Ocean acidification global warming fIsh invertebrates
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Are control of extracellular acid-base balance and regulation of skeleton genes linked to resistance to ocean acidification in adult sea urchins?

2020

SCOPUS: ar.j

Settore BIO/07 - EcologiaCO2 ventsEnvironmental EngineeringClimate ChangeOceans and SeasMechanical propertiesAcid–base homeostasisEnvironnement et pollutionDICGene expressionExtracellularEnvironmental ChemistryAnimalsSeawaterWaste Management and DisposalGeneSkeletonCO2 ventAcid-Base EquilibriumResistance (ecology)ChemistryOcean acidificationOcean acidificationCarbon DioxideHydrogen-Ion ConcentrationbiomineralizationPollutionSkeleton (computer programming)adult sea urchinsCell biologyTechnologie de l'environnement contrôle de la pollutionqPCRSea UrchinsTraitement des déchetsGene expressionEchinodermsThe Science of the total environment
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Effects of ocean acidification on rocky shore communities at Vulcano Island

2010

Settore BIO/07 - EcologiaClimate change volcanic vent ocean acidification benthos Mediterranean
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Seagrass response to high CO2 in volcanic vents

2012

Settore BIO/07 - EcologiaCymodocea nodosa Posidonia oceanica ocean acidification CO2 vents
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Seagrass community metabolism in a Mediterranean volcanic vent

2012

Settore BIO/07 - EcologiaCymodocea nodosa ocean acidification pH productivity respiration
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Evidences on alterations in skeleton composition and mineralization in a site-attached fish under naturally acidified conditions in a shallow CO2 vent

2021

Abstract Background Ocean acidification may affect fish mineralized structures (i.e. otoliths and skeleton). Methods Here, we compared the elemental composition of muscle and skeleton and the mineral features of skeleton in the site-attached fish Gobius bucchichi naturally exposed to high pCO2/low pH conditions in a shallow CO2 vent with fish of the same species exposed to normal pH. Results Overall, no skeleton malformations were found in both pH conditions, but among-site differences were found in the elemental composition. Interestingly, higher Ca/P values, inducing a moderate skeleton maturation, were found in fish exposed to acidified conditions than in controls. Conclusion Our finding…

Settore BIO/07 - EcologiaElemental compositionSettore GEO/06 - MineralogiaEnvironmental Engineering010504 meteorology & atmospheric sciencesbiologyChemistryOcean acidification010501 environmental sciencesbiology.organism_classification01 natural sciencesPollutionMineralization (biology)GobiusEnvironmental chemistryEnvironmental Chemistry14. Life underwaterSkeletal structure Skeletal composition Gobius bucchichi Metals bioaccumulation Infrared spectroscopy Ocean acidificationWaste Management and Disposal0105 earth and related environmental sciences
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