132 research outputs found
Estat de conservació de les praderies de Posidonia oceanica (Linnaeus) Delile, 1813 dins la Badia de Portocolom (Mallorca)
[cat] Posidonia oceanica (Linnaeus), Delile, 1813 és una fanerògama marina endèmica del Mediterrani que proporciona gran quantitat de serveis ecosistèmics i és clau per a la conservació de la biodiversitat. Com la majoria de la vegetació marina està en greu recessió. Una de les principals amenaces que afecten aquesta planta, juntament amb l’eutrofització i l’escalfament global, és el fondeig incontrolat. En aquest estudi fem una avaluació de l’estat de conservació de la praderia de P. oceanica situada davant la platja de s’Arenal a la badia de Portocolom afectada per fondeig incontrolat. La mitjana del percentatge de cobertura entre una fondària de 2 i 4.8 metres va ser de 44.2 ± 13.6 %, cobertures inferiors a les reportades anteriorment per aquesta zona. Les densitats van variar entre 392 i 576 feixos/m2, amb una mitjana de 508 ± 31 feixos/m2. Aquesta praderia té molt baixa densitat, o densitat anormal, indicant que està sotmesa a pressions que posen en perill el seu estat de conservació. Vam poder estimar el nombre de feixos arrabassats per una àncora d’un vaixell d’uns 15 metres d’eslora, que va ser de 165 ± 31 feixos. Aquesta praderia necessitaria 5 anys en condicions òptimes per poder recolonitzar l’àrea arrabassada per aquesta àncora. Una estima del carboni alliberat per l’efecte del fondeig d’aquesta àncora revelaria que 915 g de carboni quedaria disponible i podria ser alliberat a l’atmosfera.[eng] Posidonia oceanica (Linnaeus), Delile, 1813 is an endemic Mediterranean seagrass that provides multiple ecosystem services and is a key species for biodiversity conservation. Like most submerged vegetation, this key habitat is regressing alarmingly. One of the main threats affecting this seagrass, together with eutrophication and global warming, is uncontrolled anchoring. Here, we evaluate the conservation status of the P. oceanica meadow in front of s’Arenal beach in Portocolom Bay that is affected by uncontrolled anchoring. The mean cover percentage at depths between 2 and 4.8 meters was 44.2 ± 13.6 %, lower than previously reported for this area. Densities varied between 392 and 576 shoots/m2, with an average of 508 ± 31 shoots/m2. This is a very low, or even an abnormal, density, indicating that this meadow is subject to pressures that are threatening its conservation. We could estimate the number of shoots that were torn off by the action of anchoring of a 15 m long boat: 165 ± 31 shoots. This meadow would require 5 years of optimal conditions to be able to recolonize the area removed by the action of this anchoring. An estimate of the carbon released by the action of this anchoring was 915 g of carbon that could become available and could be released to the atmosphere
Warming effect on nitrogen fixation in Mediterranean macrophyte sediments
The Mediterranean Sea is warming faster than the global ocean, with important
consequences for organisms and biogeochemical cycles. Warming is a major
stressor for key marine benthic macrophytes. However, the effect of warming
on marine N2 fixation remains unknown, despite the fact that the high
productivity of macrophytes in oligotrophic waters is partially sustained by
the input of new nitrogen (N) into the system by N2 fixation. Here,
we assess the impact of warming on the N2 fixation rates of three key
marine macrophytes: Posidonia oceanica, Cymodocea nodosa,
and Caulerpa prolifera. We experimentally measured N2
fixation rates in vegetated and bare sediments at temperatures encompassing
current summer mean (25 and 27 ∘C), projected summer mean (29 and
31 ∘C), and projected summer maximum (33 ∘C) seawater
surface temperatures (SSTs) by the end of the century under a scenario of
moderate greenhouse gas emissions. We found that N2 fixation rates
in vegetated sediments were 2.8-fold higher than in bare sediments at current
summer mean SST, with no differences among macrophytes. Currently, the
contribution of N2 fixation to macrophyte productivity could
account for up to 7 %, 13.8 %, and 1.8 % of N requirements for
P. oceanica, C. nodosa, and C. prolifera,
respectively. We show the temperature dependence of sediment N2
fixation rates. However, the thermal response differed for vegetated
sediments, in which rates showed an optimum at 31 ∘C followed by a
sharp decrease at 33 ∘C, and bare sediments, in which rates increased
along the range of the experimental temperatures. The activation energy and
Q10 were lower in vegetated than bare sediments, indicating the lower
thermal sensitivity of vegetated sediments. The projected warming is expected
to increase the contribution of N2 fixation to Mediterranean
macrophyte productivity. Therefore, the thermal dependence of N2
fixation might have important consequences for primary production in coastal
ecosystems in the context of warming.</p
Temporal and spatial dynamics of large lake hypoxia: Integrating statistical and three‐dimensional dynamic models to enhance lake management criteria
Hypoxia or low bottom water dissolved oxygen (DO) is a world‐wide problem of management concern requiring an understanding and ability to monitor and predict its spatial and temporal dynamics. However, this is often made difficult in large lakes and coastal oceans because of limited spatial and temporal coverage of field observations. We used a calibrated and validated three‐dimensional ecological model of Lake Erie to extend a statistical relationship between hypoxic extent and bottom water DO concentrations to explore implications of the broader temporal and spatial development and dissipation of hypoxia. We provide the first numerical demonstration that hypoxia initiates in the nearshore, not the deep portion of the basin, and that the threshold used to define hypoxia matters in both spatial and temporal dynamics and in its sensitivity to climate. We show that existing monitoring programs likely underestimate both maximum hypoxic extent and the importance of low oxygen in the nearshore, discuss implications for ecosystem and drinking water protection, and recommend how these results could be used to efficiently and economically extend monitoring programs.Key Points:We modeled seasonal and spatial dynamics of Lake Erie hypoxiaWe showed hypoxia starts nearshore and can persist after traditional monitoring programs endWe recommend monitoring adjustments and explore impacts of different hypoxia definitionsPeer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/133547/1/wrcr22074.pdfhttp://deepblue.lib.umich.edu/bitstream/2027.42/133547/2/wrcr22074-sup-0001-2015WR018170-s01.pdfhttp://deepblue.lib.umich.edu/bitstream/2027.42/133547/3/wrcr22074_am.pd
The Impact of Global Warming and Anoxia on Marine Benthic Community Dynamics: an Example from the Toarcian (Early Jurassic)
The Pliensbachian-Toarcian (Early Jurassic) fossil record is an archive of natural data of benthic community response to global warming and marine long-term hypoxia and anoxia. In the early Toarcian mean temperatures increased by the same order of magnitude as that predicted for the near future; laminated, organic-rich, black shales were deposited in many shallow water epicontinental basins; and a biotic crisis occurred in the marine realm, with the extinction of approximately 5% of families and 26% of genera. High-resolution quantitative abundance data of benthic invertebrates were collected from the Cleveland Basin (North Yorkshire, UK), and analysed with multivariate statistical methods to detect how the fauna responded to environmental changes during the early Toarcian. Twelve biofacies were identified. Their changes through time closely resemble the pattern of faunal degradation and recovery observed in modern habitats affected by anoxia. All four successional stages of community structure recorded in modern studies are recognised in the fossil data (i.e. Stage III: climax; II: transitional; I: pioneer; 0: highly disturbed). Two main faunal turnover events occurred: (i) at the onset of anoxia, with the extinction of most benthic species and the survival of a few adapted to thrive in low-oxygen conditions (Stages I to 0) and (ii) in the recovery, when newly evolved species colonized the re-oxygenated soft sediments and the path of recovery did not retrace of pattern of ecological degradation (Stages I to II). The ordination of samples coupled with sedimentological and palaeotemperature proxy data indicate that the onset of anoxia and the extinction horizon coincide with both a rise in temperature and sea level. Our study of how faunal associations co-vary with long and short term sea level and temperature changes has implications for predicting the long-term effects of “dead zones” in modern oceans
Large scale patterns in vertical distribution and behavior of mesopelagic scattering layers
Recent studies suggest that previous estimates of mesopelagic biomasses are severely biased, with
the new, higher estimates underlining the need to unveil behaviourally mediated coupling between shallow and deep ocean habitats. We analysed vertical distribution and diel vertical migration (DVM)
of mesopelagic acoustic scattering layers (SLs) recorded at 38 kHz across oceanographic regimes encountered during the circumglobal Malaspina expedition. Mesopelagic SLs were observed in all areas covered, but vertical distributions and DVM patterns varied markedly. The distribution of mesopelagic backscatter was deepest in the southern Indian Ocean (weighted mean daytime depth: WMD 590 m) and shallowest at the oxygen minimum zone in the eastern Pacific (WMD 350 m). DVM was evident in all areas covered, on average ~50% of mesopelagic backscatter made daily excursions from mesopelagic depths to shallow waters. There were marked differences in migrating proportions between the regions, ranging from ~20% in the Indian Ocean to ~90% in the Eastern Pacific. Overall the data suggest strong spatial gradients in mesopelagic DVM patterns, with implied ecological and biogeochemical consequences. Our results suggest that parts of this spatial variability can be explained by horizontal patterns in physical-chemical properties of water masses, such as oxygen, temperature and turbidity.En prensa2,927
Global cooling as a driver of diversification in a major marine clade
Climate is a strong driver of global diversity and will become increasingly important as human influences drive temperature changes at unprecedented rates. Here we investigate diversification and speciation trends within a diverse group of aquatic crustaceans, the Anomura. We use a phylogenetic framework to demonstrate that speciation rate is correlated with global cooling across the entire tree, in contrast to previous studies. Additionally, we find that marine clades continue to show evidence of increased speciation rates with cooler global temperatures, while the single freshwater clade shows the opposite trend with speciation rates positively correlated to global warming. Our findings suggest that both global cooling and warming lead to diversification and that habitat plays a role in the responses of species to climate change. These results have important implications for our understanding of how extant biota respond to ongoing climate change and are of particular importance for conservation planning of marine ecosystems
Temperature dependence of CO2-enhanced primary production in the European Arctic Ocean
The Arctic Ocean is warming at two to three times the global rate1 and is perceived to be a bellwether for ocean acidification2, 3. Increased CO2 concentrations are expected to have a fertilization effect on marine autotrophs4, and higher temperatures should lead to increased rates of planktonic primary production5. Yet, simultaneous assessment of warming and increased CO2 on primary production in the Arctic has not been conducted. Here we test the expectation that CO2-enhanced gross primary production (GPP) may be temperature dependent, using data from several oceanographic cruises and experiments from both spring and summer in the European sector of the Arctic Ocean. Results confirm that CO2 enhances GPP (by a factor of up to ten) over a range of 145–2,099 μatm; however, the greatest effects are observed only at lower temperatures and are constrained by nutrient and light availability to the spring period. The temperature dependence of CO2-enhanced primary production has significant implications for metabolic balance in a warmer, CO2-enriched Arctic Ocean in the future. In particular, it indicates that a twofold increase in primary production during the spring is likely in the Arctic
Oxygen: A Fundamental Property Regulating Pelagic Ecosystem Structure in the Coastal Southeastern Tropical Pacific
Background: In the southeastern tropical Pacific anchovy (Engraulis ringens) and sardine (Sardinops sagax) abundance have recently fluctuated on multidecadal scales and food and temperature have been proposed as the key parameters explaining these changes. However, ecological and paleoecological studies, and the fact that anchovies and sardines are favored differently in other regions, raise questions about the role of temperature. Here we investigate the role of oxygen in structuring fish populations in the Peruvian upwelling ecosystem that has evolved over anoxic conditions and is one of the world's most productive ecosystems in terms of forage fish. This study is particularly relevant given that the distribution of oxygen in the ocean is changing with uncertain consequences. Methodology/Principal Findings: A comprehensive data set is used to show how oxygen concentration and oxycline depth affect the abundance and distribution of pelagic fish. We show that the effects of oxygen on anchovy and sardine are opposite. Anchovy flourishes under relatively low oxygen conditions while sardine avoid periods/areas with low oxygen concentration and restricted habitat. Oxygen consumption, trophic structure and habitat compression play a fundamental role in fish dynamics in this important ecosystem. Conclusions/Significance: For the ocean off Peru we suggest that a key process, the need to breathe, has been neglected previously. Inclusion of this missing piece allows the development of a comprehensive conceptual model of pelagic fish populations and change in an ocean ecosystem impacted by low oxygen. Should current trends in oxygen in the ocean continue similar effects may be evident in other coastal upwelling ecosystems
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