Auswahl der wissenschaftlichen Literatur zum Thema „Aquatic ecosystems“

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Zeitschriftenartikel zum Thema "Aquatic ecosystems"

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Chai, Xeai Li, H. Rohasliney und I. S. Kamaruddin. „Evaluating the Tropical Reservoir Health by using the Index of Biotic Integrity as a Management Tool for Resource Conservation Planning“. Sains Malaysiana 51, Nr. 12 (31.12.2022): 3897–907. http://dx.doi.org/10.17576/jsm-2022-5112-03.

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Biotic Integrity index (IBI) is widely utilized for biomonitoring in aquatic ecosystems, especially in assessing aquatic ecosystem health worldwide. Environmental changes significantly impact the aquatic ecosystem’s health of Subang Reservoir, which consequently affects the aquatic biodiversity. This study was conducted to determine its ecosystem’s health by assessing the IBI of freshwater fish in Subang Reservoir. In this study, thirty-four metrics were firstly selected as candidate metrics, and later, these thirty-four metrics underwent several statistical tests such as range, responsiveness, redundancy, and metrics scoring to screen and select the most appropriate metrics. A final eight metrics were selected after the statistical analysis, and a total score of 24 indicated that the Subang Reservoir’s ecosystem shows some stress due to an imbalanced fish guild. This showed that the ecosystem’s health of Subang Reservoir is in fair condition. This is because of the limitation of fish entering Subang Reservoir. The implementation of biomonitoring can be improved by modifying and selecting the most appropriate techniques, and the usage of biomonitoring can be increased in Malaysia’s freshwater ecosystems. The result reported in this study can be used as a scientific base data for implementing biomonitoring.
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De, Mitu, Chayanika Roy, Suchismita Medda, Sulagna Roy und Santi Ranjan Dey. „Diverse role of Macrophytes in aquatic ecosystems: A brief review“. INTERNATIONAL JOURNAL OF EXPERIMENTAL RESEARCH AND REVIEW 19 (30.08.2019): 40–48. http://dx.doi.org/10.52756/ijerr.2019.v19.005.

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The aquatic ecosystem is composed of aquatic flora and fauna which interact together in maintaining the aquatic ecosystem. Aquatic macrophytes are macroscopic forms of aquatic vegetation, including macro algae, mosses, ferns and angiosperms found in aquatic habitat. Macrophytes of freshwater ecosystems have diverse roles to play in the structure and functioning of these aquatic ecosystems. The depth, density, diversity and types of macrophytes present in a system are indicators of water body health. Aquatic vegetation can influence the water quality too. Macrophytes are considered as an important component of the aquatic ecosystem as the habitat and food source for aquatic life. Of all the biological treatments for controlling eutrophication, submerged macrophytes, has been recognized as being the most effective. This paper is a brief review of the diverse role of macrophytes in an aquatic ecosystem.
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Cahya Putri Rifiah, Amelia, Sacinta Julia Astasagita und Rony Irawanto. „PEMULIHAN PERAIRAN TERCEMAR MENGGUNAKAN MAKROFITA AIR“. Prosiding SEMSINA 4, Nr. 01 (09.12.2023): 314–21. http://dx.doi.org/10.36040/semsina.v4i01.8117.

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Indonesia possesses a potential and diverse biodiversity of plants that can be utilized as phytoremediation agents. One of the ecosystems frequently encountering pollution is the aquatic ecosystem. Therefore, this research is conducted to identify the diversity of aquatic macrophytes with the potential for water remediation efforts. The method employed is qualitative descriptive based on literature review. The literature study revealed 30 species of aquatic macrophytes, with 15 species prominently utilized for environmental remediation. Among these, Ipomea aquatica and Scirpus grossus emerge as the most widely employed aquatic macrophytes.
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Clifford, Chelsea, und James Heffernan. „Artificial Aquatic Ecosystems“. Water 10, Nr. 8 (17.08.2018): 1096. http://dx.doi.org/10.3390/w10081096.

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As humans increasingly alter the surface geomorphology of the Earth, a multitude of artificial aquatic systems have appeared, both deliberately and accidentally. Human modifications to the hydroscape range from alteration of existing waterbodies to construction of new ones. The extent of these systems makes them important and dynamic components of modern landscapes, but their condition and provisioning of ecosystem services by these systems are underexplored, and likely underestimated. Instead of accepting that artificial ecosystems have intrinsically low values, environmental scientists should determine what combination of factors, including setting, planning and construction, subsequent management and policy, and time, impact the condition of these systems. Scientists, social scientists, and policymakers should more thoroughly evaluate whether current study and management of artificial aquatic systems is based on the actual ecological condition of these systems, or judged differently, due to artificiality, and consider resultant possible changes in goals for these systems. The emerging recognition and study of artificial aquatic systems presents an exciting and important opportunity for science and society.
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Den Hartog, C. „Managed aquatic ecosystems“. Aquaculture 76, Nr. 1-2 (Januar 1989): 176–78. http://dx.doi.org/10.1016/0044-8486(89)90264-0.

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Korsgaard, Louise, und Jesper S. Schou. „Economic valuation of aquatic ecosystem services in developing countries“. Water Policy 12, Nr. 1 (01.11.2009): 20–31. http://dx.doi.org/10.2166/wp.2009.124.

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An important challenge of integrated water resources management (IWRM) is to balance water allocation between different users. While economically and/or politically powerful users have well developed methods for quantifying and justifying their water needs, this is not the case for ecosystems—the silent water user. A promising way of placing aquatic ecosystems on the water agenda is by economic valuation of services sustained by ecosystems. In developing countries, the livelihoods of rural people often depend directly on the provision of aquatic ecosystem services. In such situations, economic valuation of ecosystem services becomes particularly challenging. This paper reviews recent literature on economic valuation of aquatic ecosystem services in developing countries. “Market price” is the most widespread method used for valuating marketed ecosystem services in developing countries. “Cost based” and “revealed preference” methods are frequently used when ecosystem services are non-marketed. A review of 27 existing valuation studies reveals a considerable range of estimated total economic value of aquatic ecosystem services in developing countries, that is from US$30 to 3,000/ha/year. The paper concludes that economic valuation is vital for bringing ecosystems to decision-making agendas in developing countries and that great effort must be made to bridge the gap between scientists and decision makers.
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Ellsworth, J. „Systemic Barriers to the Restoration of Aquatic Ecosystems“. Water Quality Research Journal 32, Nr. 2 (01.05.1997): 235–44. http://dx.doi.org/10.2166/wqrj.1997.017.

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Abstract An ecosystem perspective is interdisciplinary and holistic, recognizing the interconnections among ecosystem components. The ecosystem approach incorporates social, economic and environmental elements into its definition (Environment Canada 1995). In instances where ecosystem initiatives fail to generate the body of public and political support necessary to address complex issues, barriers can often be found in the ecosystem initiatives themselves. Systemic barriers to the restoration of aquatic ecosystems are generated by the reluctance of some initiatives to go beyond pure sciences and an inability to integrate social, economic and environmental interests. It is common practice to allow the issues at hand to define the scale of an ecosystem initiative. Experience has shown that the issues at hand can also define the appropriate level of engagement. This paper explores Level 3: Community-Based Ecosystem Initiatives and the qualities that enable Level 3 initiatives to avoid and overcome systemic barriers to the restoration of aquatic ecosystems.
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Sánchez-Carrillo, Salvador, und Miguel Álvarez-Cobelas. „Stable isotopes as tracers in aquatic ecosystems“. Environmental Reviews 26, Nr. 1 (März 2018): 69–81. http://dx.doi.org/10.1139/er-2017-0040.

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The addition of stable isotopes (SI) of 13C and 15N has been used to study several aquatic processes, thus avoiding environmental disturbance by the observer. This approach, employed for the last three decades, has contributed to expanding our knowledge of food-web ecology and nutrient dynamics in aquatic systems. Currently, SI addition is considered a powerful complementary tool for studying several ecological and biogeochemical processes at the whole-aquatic-ecosystem scale, which could not be addressed otherwise. However, their contributions have not been considered jointly nor have they been evaluated with a view to assessing the reliability and scope of their results from an ecosystem perspective. We intend to bridge this gap by providing a comprehensive review (78 scientific publications reporting in situ 13C/15N additions at the whole-aquatic-ecosystem scale) addressing the main results arising from their use as tracers. Specifically, we focus on: (i) reasons for SI additions at the whole-ecosystem scale to study ecological processes, (ii) the paradigms resulting from its use and the insights achieved, (iii) uncertainties and drawbacks arising from these SI addition experiments, and (iv) the potential of this approach for tackling new paradigms. SI tracer addition at the ecosystem scale has provided new functional insights into numerous ecological processes in aquatic sciences (importance of subsidies in lakes; heterotrophy dominance in benthic food webs in lakes, wetlands and estuaries; the decrease in N removal efficiency in most aquatic ecosystems due to anthropogenic alteration; the recognition of hyporheic zones and floodplains as hot spots for stream denitrification; and high rates of internal N recycling in tidal freshwater marshes). However, certain constraints such as the high cost of isotopes, the maintenance of the new isotopic steady state, and avoidance of biomass changes in any compartment or pool during tracer addition bear witness to the difficulties of applying this approach to all fields of aquatic ecology and ecosystems. The future development of this approach, rather than expanding to larger and complex aquatic ecosystems, should include other stable isotopes such as phosphorus (P18O4).
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Jorgensen, S. E. „Recent Trends in the Development of Ecological Models Applied on Aquatic Ecosystems“. Scientific World JOURNAL 2 (2002): 387–406. http://dx.doi.org/10.1100/tsw.2002.89.

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This paper presents an overview of the application of models on aquatic ecosystems. More than 17% of the models published in the focal journal in the field, Ecological Modelling, are aquatic ecosystem models. An increasing number of papers are dealing with the theoretical aspects of modeling – new modeling approaches and techniques, how models can be used to reveal ecosystem properties, and how models can better reflect the properties of ecosystems. This development implies that today we have more types of models. The characteristics, the advantages, and the disadvantages of these model types are presented briefly. The selection criteria for the presented model types are discussed, and the application of these types to models for aquatic ecosystems is reviewed. A recent improvement in model calibration of particular interest for aquatic ecosystems is presented, and the perspectives resulting from this new calibration procedure and from possible hybrids of the presented model types are discussed.
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Adhikari, Namita Paudel, Subash Adhikari und Ganesh Paudel. „Bacterial Diversity in Aquatic Ecosystems over the Central Himalayas, Nepal: Progress and Future Perspectives“. Janapriya Journal of Interdisciplinary Studies 8 (31.12.2019): 200–211. http://dx.doi.org/10.3126/jjis.v8i0.27319.

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Nepal hosts a large area of freshwater aquatic ecosystem including glacier associated system like glacier-fed streams and lakes as well as stream fed lowland lakes. Bacteriological studies are very important in aquatic ecosystems as bacteria are the major participants in biogeochemical cycles and food web structures. This study reviewed available literature in bacteriological studies of aquatic ecosystems in the Central Himalayas, Nepal and revealed that such studies are very limited. Thus, we conclude that future research works need to proceed through the latest molecular methods with high throughput technique using multiple environmental factors in the aquatic ecosystem.
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Dissertationen zum Thema "Aquatic ecosystems"

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Palesse, Stephanie. „Déterminisme de la décision lysogénique au sein des communautés virales aquatiques : importance des fluctuations physiologiques et métaboliques des hôtes procaryotes“. Thesis, Clermont-Ferrand 2, 2014. http://www.theses.fr/2014CLF22520.

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Tan, Xiang. „Environmental Influences on Benthic Algal Communities and their Application for Biomonitoring of Australian and Chinese Rivers“. Thesis, Griffith University, 2015. http://hdl.handle.net/10072/367601.

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Benthic algae a re one of the most important primary producers i n lotic ecosystems, and changes i n their community structure and function (e.g., metabolism) will influence other organisms at higher trophic levels or even the entire aquatic ecosystem through bottom-up effects. Since they are known to be sensiti ve to changes i n ambient conditions, benthic algae and especially diatoms have been widely used as i ndicators of environmental changes in aquatic ecosystems, particular ly i n E urope , through developi ng diatom-based indices. However, these indices have not been widely used i n other continents. Applications of such i ndices in Asia and Oceania first require testi ng to see whether the y can perform as reliable bioindicators across time and space, considering that aquatic systems are constantly changing in terms of their ambient environment such as water physical and chemical conditions. Nevertheless, few studies have been carried out to compare the environmental influences on benthic algal communities among different geographic regions, nor the influences at different spatial scales (e.g., catchment, reach, and habitat). F urthermore, few studies have considered how diatom indices perform compare with other commonly used bioindicators of aquatic ecosystem health.
Thesis (PhD Doctorate)
Doctor of Philosophy (PhD)
Griffith School of Environment.
Science, Environment, Engineering and Technology
Full Text
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Perusse, Martin. „Metal cycling in terrestrial and aquatic ecosystems“. Thesis, McGill University, 1990. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=59848.

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The present study examines the cycling of elements in the biosphere. The first chapter proposes a theoretical framework for this cycling based on both metal/ligand theory and mass balance studies. Empirical modelling serves as an alternative and complement to mass balance studies in predicting the export of elements from watersheds. Watershed output (export per unit area per unit of time) is predicted using atmospheric deposition rates, an element bonding strength index, the watershed area and a forest classification (deciduous vs coniferous). Finally the last chapter examines, in a speculative fashion, the partitioning of elements between the atmosphere and hydrosphere as a function of element behaviour and discusses the ecological consequences of human activity on this partitioning.
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Gjata, Nerta. „Food Web Simulation Studies on Aquatic Ecosystems“. Doctoral thesis, Università degli studi di Trento, 2013. https://hdl.handle.net/11572/367707.

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There is an increasing interest in dynamical food web modeling, and recent advances of computational biology provide new algorithms and tools for modern systems ecology. In this work stochastic individual-based models are used for simulating food web dynamics in two case studies: the Kelian river, in Borneo, Indonesia and a marine ecosystem in Gulf of Guinea. The two cases present effects from human perturbations. In both cases, we constructed food webs, based on real databases. We parameterized the stochastic dynamical model for the system models and performed sensitivity analysis (and community response indicators) in order to quantify the relative importance of system components. The main aims are to understand the importance of functional diversity of aquatic ecosystems and relations between the dynamics of species and the whole community in perturbed ecosystems due to human activities (pollution due to gold mining activity and human settlements in the case of the Kelian river ecosystem and the impact of Fish Aggregation Devices on skipjack tuna communities in the case of the Gulf of Guinea ecosystem). In Kelian river case, our results suggest that invertebrate shredders are indicators of human impact on the river. In downstream sites our results show that the river is more polluted and the relative importance of grazers and shredders decrease. The primary producers disappear downstream as consequence of mine activity and human waste. In the marine system case study, we analyzed the effects of association between tunas and FADs, and compared this to the behavior of free tuna individuals. The results suggest that skipjack tuna is affected by the use of FADs as fishing strategy on them. Some individual species show more sensibility to variation of population size of tuna. These two studies contribute to better understand how functional diversity is related to human impact. This kind of approach may help in shaping systems-based conservation and marine fisheries management strategies. Keywords: food web, aquatic ecosystems, stochastic model, sensitivity analysis
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Gjata, Nerta. „Food Web Simulation Studies on Aquatic Ecosystems“. Doctoral thesis, University of Trento, 2013. http://eprints-phd.biblio.unitn.it/1140/1/TesiN_Gjata.pdf.

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There is an increasing interest in dynamical food web modeling, and recent advances of computational biology provide new algorithms and tools for modern systems ecology. In this work stochastic individual-based models are used for simulating food web dynamics in two case studies: the Kelian river, in Borneo, Indonesia and a marine ecosystem in Gulf of Guinea. The two cases present effects from human perturbations. In both cases, we constructed food webs, based on real databases. We parameterized the stochastic dynamical model for the system models and performed sensitivity analysis (and community response indicators) in order to quantify the relative importance of system components. The main aims are to understand the importance of functional diversity of aquatic ecosystems and relations between the dynamics of species and the whole community in perturbed ecosystems due to human activities (pollution due to gold mining activity and human settlements in the case of the Kelian river ecosystem and the impact of Fish Aggregation Devices on skipjack tuna communities in the case of the Gulf of Guinea ecosystem). In Kelian river case, our results suggest that invertebrate shredders are indicators of human impact on the river. In downstream sites our results show that the river is more polluted and the relative importance of grazers and shredders decrease. The primary producers disappear downstream as consequence of mine activity and human waste. In the marine system case study, we analyzed the effects of association between tunas and FADs, and compared this to the behavior of free tuna individuals. The results suggest that skipjack tuna is affected by the use of FADs as fishing strategy on them. Some individual species show more sensibility to variation of population size of tuna. These two studies contribute to better understand how functional diversity is related to human impact. This kind of approach may help in shaping systems-based conservation and marine fisheries management strategies. Keywords: food web, aquatic ecosystems, stochastic model, sensitivity analysis
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Holland, Angela. „BRIDGING AQUATIC AND TERRESTRIAL ECOSYSTEMS: ECOLOGY OF SEMI-AQUATIC MAMMALS IN SOUTHERN ILLINOIS“. OpenSIUC, 2016. https://opensiuc.lib.siu.edu/dissertations/1269.

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Mammals in freshwater aquatic systems play important roles as ecosystem engineers, trophic transfer agents, and apex predators, thus acting as indicators of freshwater ecosystem function. Watersheds inhabited by semi-aquatic mammals have increased links between adjacent terrestrial and aquatic ecosystems compared to watersheds where they are not present. Semi-aquatic mammals not only exert top-down influences on streams, but are affected by bottom-up forces from the riparian system itself. The goal of this study was to identify variables that correlate with the presence of beaver (Castor canadensis), muskrat (Ondatra zibethicus), mink (Neovison vison), and river otter (Lontra canadensis), including their interactions, resulting in a better understanding of the areas where these semi-aquatic mammals occur and their effects on the riparian system. The objectives of this study were (1) to identify variables related to the probability of detection, initial occupancy, colonization, and extinction of the 4 semi-aquatic mammals in southern Illinois; and (2) to test if the reintroduction of river otter has changed stream food webs. To address my first objective, I sampled 120 bridge sites in 2 periods (winter: Jan-Feb; and spring: Mar-Apr) during 2012–2014 in 11 major watersheds in the southern third of Illinois (44,526 km2) to estimate multi-season occupancy. Each survey unit was a 400-m stream segment visited twice by 2 observers for a total of 4 observations per site per period. Observers recorded all mammal signs found, including sign species and type. Sites were Intensive Basin Survey Sites sampled by Illinois Department of Natural Resources (IDNR) and Illinois Environmental Protection Agency (IEPA), allowing data collected by the state to be available for explanatory variables for mammal occupancy. Data collected by the Illinois Natural History Survey (INHS) also were available for a subset of sites. I collected local- and landscape-scale habitat and weather variables for each site. I developed hypotheses regarding occupancy of sites based on land-cover, human disturbance, and stream attributes for each species. I developed additional hypotheses regarding prey availability and water quality for river otter and mink. Sites used in each analysis were dependent on data available to address the hypotheses of interest. Beaver and muskrat were present at ≥100 of 103 sites for ≥1 observation. Naïve occupancy was high (≥82%) every year for both species. Detection probabilities for beaver and muskrat were best predicted by survey period. Beaver detection remained fairly constant across survey periods except for a decrease in winter 2014, whereas muskrat detection was generally lower during winter and higher during spring. Beaver were more likely to occupy larger streams than smaller streams during the initial survey period. Sites that lacked a dominant land-cover had a lower probability of beaver colonization than sites dominated by agriculture or woody vegetation at the landscape scale. In addition, the probability that a site would be colonized by beaver during the study increased with availability of water within 1 km of the surveyed segment, increased stream density, sites at larger streams, and river otter presence during the previous period. The probability of site extinction decreased as stream size, stream density within 1 km, and water availability within 500 m of the survey segment increased. Occupancy of muskrat during the initial survey period was negatively predicted by % forest in the 1-km riparian area, channel incision, and amount mercury in the sediment. Colonization by muskrats was lower during the long spring to winter intervals than the short winter to spring intervals, and was positively related to the amount of organic carbon in the sediment. The probability of site extinction by muskrat increased with increasing % forest within the riparian area around the stream segment, decreasing 1-km stream density, and when land-cover within 1 km of sites was dominated by agriculture or woody vegetation. Multi-season occupancy of river otter and mink were assessed in 2 separate analyses that used either land-cover and management variables or prey availability and riparian community composition, respectively. In the first analysis, river otter and mink were present at ≥84 of 103 sites. Naïve occupancy was higher every year for mink (≥88.3%) than for river otter (≥55.3%). Detection of river otter and mink in the first analysis increased as substrate availability increased. Occupancy of river otter during the initial survey period was predicted by large stream size, low % developed area within 250 m of the surveyed segment, and proximity to nearest river otter reintroduction point. Probability of colonization by river otter varied by survey period and was higher at sites with larger streams, higher stream density, lower % developed area, and within a known river otter population area. Site extinction by river otter in the first analysis varied by survey period and was linked to increased organic carbon in the sediment, and decreased road density within 1 km of the surveyed segment. River otter harvest was not found to affect site colonization or extinction. Mink occupancy during the initial period was negatively associated with water availability within 100 m of the survey segment. Site colonization by mink varied by month and increased with increasing developed area within 100 m of the surveyed segment, increasing channel incision, and decreasing rainfall. Probability of site extinction for mink increased as stream size and developed area within 500 m of the surveyed segment increased, and when woody vegetation was the dominant land-cover type within 1 km of the surveyed segment. The second analysis of multi-season occupancy of river otter and mink used 77 sites, 81.8% of which had ≥1 river otter detection in the study and 98.7% of which had ≥1 mink detection. Naïve occupancy differed between years but gradually increased for river otter and remained high (≥93.5%) for mink. Increasing substrate availability increased the probability of river otter detection, whereas mink detection varied by survey period. Occupancy during the initial survey period was higher in sites closer to the reintroduction points for river otter. Probability of colonization of river otter was positively associated with macroinvertebrate IBI and fish species richness, sites with high fish species richness of fish families preferred by river otter also had reduced otter extinction probability. No tested variables predicted initial occupancy for mink, but mink were more likely to colonize sites with increased fish richness and when muskrat were present during the previous period. Mink had decreased probability of extinction in sites with increasing mussel community index. My results indicate that semi-aquatic mammals in Illinois were affected by a riparian habitat, water availability, and stream community variables at both the landscape and local scale. I found high occupancy of mink, beaver, and muskrat across the entire landscape of southern Illinois, and my results suggest that the geographic range of river otter continues to expand. Relationships of occupancy of these semi-aquatic mammals to measurements of urban areas and human disturbance were not consistent across all species. Mink and river otter occupancy were both predicted by aspects of prey availability, indicating the importance of predator-prey relationships in occupancy dynamics of riparian predators. Hypotheses regarding predator pressure and changes in environmental variables were used to test the effects of river otter reintroduction on stream communities. For this objective, I used structural equation models. I compared fish and macroinvertebrate communities from before (1982-1995) and after (2005-2013) reintroduction of river otter, which occurred in 1994–1996. Fish and macroinvertebrate community data for 35 sites located throughout 6 major watersheds in southern Illinois (25,550 km2) were obtained from state agencies. Changes in stream communities were evaluated using 4 metrics (species richness, species dominance, skewness in size distribution of prey, and proportion of individuals in the size class preferred by river otter). Neither the inclusion of river otter site use nor change in stream quality, measured by change in % forest, improved models over the simple model which only included fish and macroinvertebrate communities. Overall, I found no evidence that river otter presence or change in forest cover affected stream fish and macroinvertebrate communities.
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James, Joanna. „The impact of invasive crayfish on aquatic ecosystems“. Thesis, Cardiff University, 2015. http://orca.cf.ac.uk/89031/.

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Crayfish are keystone species and ecosystem engineers that affect the structure and function of aquatic ecosystems. Whilst ecological impacts are caused by crayfish in their native range, non - native crayfish species typically have a greater ef fect on some other aquatic organisms and ecosystem processes (Chapter 2). Crayfish are extremely successful invaders that often cause declines in native cra yfish (Chapter 3). Of the 7 non - native crayfish species in the UK, the signal crayfish ( Pacifastacus leniusculus ) is currently the most widespread (Chapter 3). Field and laboratory data, however, suggest that in parts of the UK signal crayfish are being outcompeted by more recently introduced virile crayfish ( Orconectes cf. virilis ) (Chapter 4). Non - native crayfish also threaten native crayfish through disease, notably crayfish plague ( Aphanomyces astaci ), transmission. Whilst non - native North American crayfish are largely resistant to A. astaci , infection in susceptible native European species is usually lethal. Within this study 23 signal crayfish populations were screened for A. astaci and 13 were infected (Chapter 5). Virile crayf ish from the UK were also infected with A. astaci , and therefore should also be considered as a transmission pathway for this pathogen in the UK (Chapter 6). Whilst the majority of studies on crayfish symbionts are focused on A. astaci , crayfish host a wid e range of micro and macro - parasites. One group of particular interest are branchiobdellidans (Annelida: Clitellata). Two species of these ectosymbionts, Xironogiton victoriensis and Cambarincola aff. okadai , were recently discovered on invasive signal cra yfish in the UK (Chapter 7). Owing to their abilities to survive for extended periods off the host and reproduce rapidly both species have a high invasion potential in the UK (Chapter 8). Laboratory experiments show that signal crayfish infested with X. victoriensis were less aggressive and poorer foragers than uninfested c rayfish , therefore these symbionts may influence signal crayfish invasion dynamics (Chapter 9).
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Kamara, Sheku. „Physiological responses of aquatic macrophytes to natural organic matter potential for structuring aquatic ecosystems“. Berlin Logos-Verl, 2008. http://d-nb.info/992155371/04.

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Bruce, Louise Christina. „A study of the interaction between the physical and ecological processes of three aquatic ecosystems /“. Connect to this title, 2005. http://theses.library.uwa.edu.au/adt-WU2007.0178.

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Ding, Yan. „Environmental Dynamics of Dissolved Black Carbon in Aquatic Ecosystems“. FIU Digital Commons, 2013. http://digitalcommons.fiu.edu/etd/846.

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Black carbon (BC), the incomplete combustion product from biomass and fossil fuel burning, is ubiquitously found in soils, sediments, ice, water and atmosphere. Because of its polyaromatic molecular characteristic, BC is believed to contribute significantly to the global carbon budget as a slow-cycling, refractory carbon pool. However, the mass balance between global BC generation and accumulation does not match, suggesting a removal mechanism of BC to the active carbon pool, most probable in a dissolved form. The presence of BC in waters as part of the dissolved organic matter (DOM) pool was recently confirmed via ultrahigh resolution mass spectrometry, and dissolved black carbon (DBC), a degradation product of charcoal, was found in marine and coastal environments. However, information on the loadings of DBC in freshwater environments and its global riverine flux from terrestrial systems to the oceans remained unclear. The main objectives of this study were to quantify DBC in diverse aquatic ecosystems and to determine its environmental dynamics. Surface water samples were collected from aquatic environments with a spatially significant global distribution, and DBC concentrations were determined by a chemical oxidation method coupled with HPLC detection. While it was clear that biomass burning was the main sources of BC, the translocation mechanism of BC to the dissolved phase was not well understood. Data from the regional studies and the developed global model revealed a strong positive correlation between DBC and dissolved organic carbon (DOC) dynamics, indicating a co-generation and co-translocation between soil OC and BC. In addition, a DOC-assistant DBC translocation mechanism was identified. Taking advantage of the DOC-DBC correlation model, a global riverine DBC flux to oceans on the order of 26.5 Mt C yr-1 (1 Mt = 1012 g) was determined, accounting for 10.6% of the global DOC flux. The results not only indicated that DOC was an important environmental intermediate for BC transfer and storage, but also provided an estimate of a major missing link in the global BC budget. The ever increasing DBC export caused by global warming will change the marine DOM quality and may have important consequences for carbon cycling in marine ecosystem.
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Bücher zum Thema "Aquatic ecosystems"

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Polunin, Nicholas V. C., Hrsg. Aquatic Ecosystems. Cambridge: Cambridge University Press, 2008. http://dx.doi.org/10.1017/cbo9780511751790.

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1953-, Kumar Arvind, Hrsg. Aquatic ecosystems. New Delhi: A.P.H. Pub. Corp., 2003.

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Aquatic ecosystems. Hauppauge, N.Y: Nova Science Publisher's, 2011.

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Gonzales, Gaudiosa A. Aquatic ecosystems. Diliman, Quezon City: University of the Philippines, Open University, 2001.

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George, Michael R., Hrsg. Managed aquatic ecosystems. Amsterdam: Elsevier, 1987.

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Kainz, Martin, Michael T. Brett und Michael T. Arts, Hrsg. Lipids in Aquatic Ecosystems. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2.

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1958-, Arts Michael Theodore, Brett Michael T und Kainz Martin J, Hrsg. Lipids in aquatic ecosystems. Dordrecht: Springer, 2009.

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1926-, Agrawal V. P., Desai B. N. 1934-, Abidi, S. A. H. 1940- und National Institute of Oceanography (India), Hrsg. Management of aquatic ecosystems. Delhi: Narendra Pub. House, 1989.

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Häder, Donat-P., E. Walter Helbling und Virginia E. Villafañe, Hrsg. Anthropogenic Pollution of Aquatic Ecosystems. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-75602-4.

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Dar, Gowhar Hamid, Khalid Rehman Hakeem, Mohammad Aneesul Mehmood und Humaira Qadri. Freshwater Pollution and Aquatic Ecosystems. New York: Apple Academic Press, 2021. http://dx.doi.org/10.1201/9781003130116.

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Buchteile zum Thema "Aquatic ecosystems"

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Melack, John M. „Aquatic Ecosystems“. In Ecological Studies, 119–48. Berlin, Heidelberg: Springer Berlin Heidelberg, 2016. http://dx.doi.org/10.1007/978-3-662-49902-3_7.

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Kumar, Har Darshan, und Donat-P. Häder. „Aquatic Ecosystems“. In Global Aquatic and Atmospheric Environment, 1–88. Berlin, Heidelberg: Springer Berlin Heidelberg, 1999. http://dx.doi.org/10.1007/978-3-642-60070-8_1.

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Werkhoven, Marga C. M., und Geert M. T. Peeters. „Aquatic macrophytes“. In The Freshwater Ecosystems of Suriname, 99–112. Dordrecht: Springer Netherlands, 1993. http://dx.doi.org/10.1007/978-94-011-2070-8_6.

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Jackson, Togwell A. „Mercury in aquatic ecosystems“. In Metal Metabolism in Aquatic Environments, 77–158. Boston, MA: Springer US, 1998. http://dx.doi.org/10.1007/978-1-4757-2761-6_5.

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Nayak, Susri, Sthitaprajna Nath Sharma, Smruti Prajna Pradhan, Subhashree Nayak und Lipika Patnaik. „Anthracene in Aquatic Ecosystems“. In Toxicity of Aquatic System and Remediation, 85–101. Boca Raton: CRC Press, 2024. http://dx.doi.org/10.1201/9781003297901-7.

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Guschina, Irina A., und John L. Harwood. „Algal lipids and effect of the environment on their biochemistry“. In Lipids in Aquatic Ecosystems, 1–24. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2_1.

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Arts, Michael T., und Christopher C. Kohler. „Health and condition in fish: the influence of lipids on membrane competency and immune response“. In Lipids in Aquatic Ecosystems, 237–56. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2_10.

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Kattner, Gerhard, und Wilhelm Hagen. „Lipids in marine copepods: latitudinal characteristics and perspective to global warming“. In Lipids in Aquatic Ecosystems, 257–80. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2_11.

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Iverson, Sara J. „Tracing aquatic food webs using fatty acids: from qualitative indicators to quantitative determination“. In Lipids in Aquatic Ecosystems, 281–308. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2_12.

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Parrish, Christopher C. „Essential fatty acids in aquatic food webs“. In Lipids in Aquatic Ecosystems, 309–26. New York, NY: Springer New York, 2009. http://dx.doi.org/10.1007/978-0-387-89366-2_13.

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Konferenzberichte zum Thema "Aquatic ecosystems"

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Zubcov, Elena, Nadejda Andreev und Dumitru Bulat. „Determinarea schimbărilor mediului acvatic, evaluarea migrației şi impactului poluanților, stabilirea legităților funcționării hidrobiocenozelor şi prevenirea consecinţelor nefaste asupra ecosistemelor (abordări, oportunități, realizări)“. In Simpozion "Modificări funcționale ale ecosistemelor acvatice în contextul impactului antropic și al schimbărilor climatice". Institute of Zoology, Republic of Moldova, 2021. http://dx.doi.org/10.53937/9789975151979.01.

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This article reflects on the main issues addressed in the AQUABIO project in the context of international provisions for the prevention of the risk of pollution of aquatic ecosystems and the need to protect/restore aquatic biodiversity. The paper presents the applied innovative tools, project stages, applied research methods and equipment as well as the main results obtained during 2020, including changes taking place in the ecosystems of the Dniester and Prut rivers under the influence of anthropogenic (water capture, dams, exploitation of rivers for energy purposes) and natural factors (meteorological conditions), which put at risk the functioning of aquatic ecosystems and their capacity for self-purification.
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Fedorova, Irina. „NONADDITIVE PARAMETERS OF ARCTIC AQUATIC ECOSYSTEMS“. In 19th SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings. STEF92 Technology, 2019. http://dx.doi.org/10.5593/sgem2019v/1.4/s02.033.

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Zhyvitskaya, E. P., E. K. Vlasenko, V. A. Stelmakh und A. G. Sysa. „METHODS FOR ASSESSING THE ECOLOGICAL CAPACITY OF NATURAL AND URBANIZED WATER SYSTEMS“. In SAKHAROV READINGS 2021: ENVIRONMENTAL PROBLEMS OF THE XXI CENTURY. International Sakharov Environmental Institute, 2021. http://dx.doi.org/10.46646/sakh-2021-1-252-255.

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Anthropogenic pollution ;rnd e^TOph^t^ of aquatic ecosystems аге дЬЬа1 problems. Especi^ly important is the problem of reducing the quality of the already limited supply of fresh water. These problems have led to а wide range of studies in the field of monitoring of water ecosystems, which allows us to assess the ecologicd state of the reservoir. The functioning of aquatic ecosystems is trgely determined by the anthropogenic ;rnd иаШта! input of biogenic elements from the environment, so to determine the environment^ sound norms of anthropogenic input of biogenic elements into the ecosystem of the reservoir, it is necessary to identify the features of the structure of phyto- ;rnd zooptnkton, macrophytes, as well as to determine the concentration of chem^l elements connmed in the water.
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Zhyvitskaya, E. P., E. K. Vlasenko, V. A. Stelmakh und A. G. Sysa. „METHODS FOR ASSESSING THE ECOLOGICAL CAPACITY OF NATURAL AND URBANIZED WATER SYSTEMS“. In SAKHAROV READINGS 2021: ENVIRONMENTAL PROBLEMS OF THE XXI CENTURY. International Sakharov Environmental Institute, 2021. http://dx.doi.org/10.46646/sakh-2021-1-252-255.

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Anthropogenic pollution ;rnd e^TOph^t^ of aquatic ecosystems аге дЬЬа1 problems. Especi^ly important is the problem of reducing the quality of the already limited supply of fresh water. These problems have led to а wide range of studies in the field of monitoring of water ecosystems, which allows us to assess the ecologicd state of the reservoir. The functioning of aquatic ecosystems is trgely determined by the anthropogenic ;rnd иаШта! input of biogenic elements from the environment, so to determine the environment^ sound norms of anthropogenic input of biogenic elements into the ecosystem of the reservoir, it is necessary to identify the features of the structure of phyto- ;rnd zooptnkton, macrophytes, as well as to determine the concentration of chem^l elements connmed in the water.
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Torok, Liliana. „OPTICAL CHARACTERIZATION OF DOBROGEAN AQUATIC ECOSYSTEMS PLATEAU“. In 15th International Multidisciplinary Scientific GeoConference SGEM2015. Stef92 Technology, 2011. http://dx.doi.org/10.5593/sgem2015/b31/s12.061.

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Shakarbaev, U. A. „HUMAN CERCARIASIS IN AQUATIC ECOSYSTEMS OF UZBEKISTAN“. In THEORY AND PRACTICE OF PARASITIC DISEASE CONTROL. All-Russian Scientific Research Institute for Fundamental and Applied Parasitology of Animals and Plant – a branch of the Federal State Budget Scientific Institution “Federal Scientific Centre VIEV”, 2023. http://dx.doi.org/10.31016/978-5-6048555-6-0.2023.24.520-525.

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The geography of human cercariasis is extensive. It covers urbanized areas of many modern metropolitan cities. Cercariasis is also known in the inland waters of the Amu Darya and Zarafshan River basins (within Uzbekistan). The causative agents of cercariasis consist of two clearly differentiated cercariae groups: Schistosoma and Bilharziella. The article presents the results of field and experimental studies on nonspecific human cercariasis caused by cercariae Schistosoma turkestanicum and Trichobilharzia ocellata in various reservoirs of Uzbekistan. In this paper, the studies were conducted in Uzbekistan in 2020–2022. The material was collected in the delta and floodplain reservoirs of the Amu Darya and Zarafshan rivers. The material was collected in the deltaic and bottomland water bodies of the Amu Darya and Zarafshan Rivers which were intensively visited by water birds and mammals. In different seasons of the year, spring, summer, and autumn, more than 25 thousand specimens of freshwater mollusks belonging to the families Lymnaeidae, Planorbidae, Physidae and Thiaridae were collected and studied. Morphological study of cercariae was conducted. In different types of reservoirs, the population of mollusks, intermediate hosts, of discussed trematodes, turned out to be quite high. Their total infection with parthenita and the cercariae bilharzia ranged from 0.3 to 6.2% in Lymnaeidae, and 4.0% in Melanoididae. Schistosome larvae (Sch. turkestanicum) infection was only recorded in Lymnaea auricularia (Lymnaeidae), which was 12.6 to 22.6%.
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Lockwood, Ronald B., Charles Bachmann, Michael Chrisp, Corrie Smeaton, Nima Pahlaven, Eric Hochberg, Marcos J. Montes et al. „Aquatic ecosystems science using an imaging spectrometer“. In Imaging Spectrometry XXVI: Applications, Sensors, and Processing, herausgegeben von Emmett J. Ientilucci und Christine L. Bradley. SPIE, 2023. http://dx.doi.org/10.1117/12.2676124.

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Pandey, Ayoni, Nivedita Rai, Shivendra Mani Tripathi und Sudhanshu Mishra. „Pharmaceutical Waste: Risks & Challenges Faced by Aquatic Ecosystem“. In International Conference on Frontiers in Desalination, Energy, Environment and Material Sciences for Sustainable Development & Annual Congress of InDA. AIJR Publisher, 2023. http://dx.doi.org/10.21467/proceedings.161.17.

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Pharmaceutical industries are experiencing a steady increase in both their numbers and demands, leading to a significant rise in the amount of waste they generate. This waste comprises various components such as organic compounds, excipients, and plastic containers. Unfortunately, a major portion of this waste is discharged into aquatic bodies through pipes, eventually reaching canal systems and ultimately the seas. This practice poses a severe threat to aquatic life, as it significantly impacts their habitat in a hazardous manner. One of the primary deleterious effects caused by pharmaceutical waste discharge is the elevation of the Biological Oxygen Demand (BOD) in the affected aquatic areas. This increase in BOD results in reduced oxygen availability for aquatic creatures, leading to mortality and ultimately causing a disruption in the natural balance of the ecosystem. Moreover, the accumulation of organic compounds from pharmaceutical waste leads to eutrophication, which accelerates the aging process of lakes, ultimately converting them into land. Another harmful consequence is biomagnification, wherein the concentration of toxicants increases as they move up the food chain through successive trophic levels. The continuous contamination of aquatic ecosystems by industrial waste is exacerbating the degradation of these fragile environments. However, the growing recognition of this issue has prompted research and implementation of various water treatment methods. These methods aim to mitigate the degradation rate and protect aquatic ecosystems from further harm. By employing advanced treatment techniques, it is possible to reduce the negative impact of pharmaceutical waste discharge and preserve the integrity of aquatic ecosystems. Efforts must be made to raise awareness among pharmaceutical industries about the importance of responsible waste management. By adopting sustainable practices and investing in environmentally friendly technologies, such as improved waste disposal systems and more efficient water treatment methods, the industry can significantly reduce its ecological footprint. Collaboration between regulatory bodies, environmental organizations, and pharmaceutical companies is essential to address this pressing issue effectively. With concerted efforts and a collective commitment to environmental stewardship, it is possible to mitigate the detrimental effects of pharmaceutical waste on aquatic ecosystems and safeguard the future of our planet's delicate aquatic habitats.
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Tian, Yongzhong, Tianxiang Yue, Yanghua Gao und Lifen Zhu. „Food potential of continental aquatic ecosystems in China“. In Optics & Photonics 2005, herausgegeben von Wei Gao und David R. Shaw. SPIE, 2005. http://dx.doi.org/10.1117/12.616046.

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Gitelson, A. A., R. Khanbilvardi, Boris Shteinman und Yosef Yacobi. „Remote Estimation of Phytoplankton Distribution in Aquatic Ecosystems“. In Ninth Biennial Conference on Engineering, Construction, and Operations in Challenging Environments. Reston, VA: American Society of Civil Engineers, 2004. http://dx.doi.org/10.1061/40722(153)36.

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Berichte der Organisationen zum Thema "Aquatic ecosystems"

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Schell, D. M. [Energy flow in arctic aquatic ecosystems]. Office of Scientific and Technical Information (OSTI), Dezember 1985. http://dx.doi.org/10.2172/10138591.

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Schell, D. M. [Energy flow in arctic aquatic ecosystems]. Office of Scientific and Technical Information (OSTI), Januar 1985. http://dx.doi.org/10.2172/6614833.

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Anderson, Elizabeth P., Sandra B. Correa, Michael Goulding und Thiago B. A. Couto. Conserving Aquatic Ecosystems in the Amazon. Wildlife Conservarion Society, 2022. http://dx.doi.org/10.19121/2022.report.45346.

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Burton, G. A. Assessing aquatic ecosystems using pore waters and sediment chemistry. Natural Resources Canada/ESS/Scientific and Technical Publishing Services, 1998. http://dx.doi.org/10.4095/306942.

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Musselman, Robert C., Laura Hudnell, Mark W. Williams und Richard A. Sommerfeld. Water chemistry of Rocky Mountain Front Range aquatic ecosystems. Ft. Collins, CO: U.S. Department of Agriculture, Forest Service, Rocky Mountain Forest and Range Experiment Station, 1996. http://dx.doi.org/10.2737/rm-rp-325.

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Mooney, Benjamin. Understanding the Efficiency of Energy Flow Through Aquatic Food Webs. Department of Aquatic Resources, Swedish University of Agricultural Sciences, 2024. http://dx.doi.org/10.54612/a.2kg9dkp0ch.

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The efficiency of energy flow through aquatic food webs is crucial for ecosystem functioning. The energy available to higher trophic levels varies across ecosystems and is influenced by factors such as nutrient availability and species composition. Recent research indicates that temperature also plays a significant role in determining energy transfer efficiency. This essay addresses the factors contributing to variability in energy flow efficiency between aquatic ecosystems, with a focus on the impacts of global climate change. It explores how food web characteristics influence energy transfer between trophic levels and examines the challenges in understanding and estimating energy flow due to complex trophic relationships, spatial subsidies, and processes across multiple biological levels. The essay highlights the dynamic response of energy flow efficiency to climate changerelated environmental changes, such as rising temperatures, altered precipitation patterns, and nutrient inputs. Additionally, it identifies gaps in our current understanding and suggests important avenues for further research to improve predictions of energy flow changes, essential for informing sustainable management strategies in the face of environmental change.
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Russ, Emily, Amy Yarnall und Safra Altman. Dredged material can benefit submerged aquatic vegetation (SAV) habitats. Engineer Research and Development Center (U.S.), August 2023. http://dx.doi.org/10.21079/11681/47423.

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This technical note (TN) was developed by the US Army Engineer Research and Development Center–Environmental Laboratory (ERDC-EL) to provide an overview of the ecosystem services delivered by submerged aquatic vegetation (SAV) to estuarine and coastal ecosystems and to describe potential methods for the beneficial use of dredged material (BUDM) to aid in SAV restoration. Although dredging tends to have a negative association with SAV habitats, BUDM may provide an opportunity to expand suitable SAV habitat to areas where depth is the primary limiting factor. Recent in situ observations have shown that SAV has opportunistically colonized several dredged-material placement sites. This TN provides context on BUDM for SAV habitat restoration to encourage increased strategic placement.
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Schad, Aaron, Daniel Allen, Lynde Dodd, Ricardo Luna, Jacob Kelly, Kristina Hellinghausen, Nathan Harms, Gary Dick und Yaretzy Charo. Aquatic ecosystem restoration in the Texas Western Gulf Coast Plain / Lower Rio Grande alluvial floodplain ecoregion : Resaca Boulevard Resaca Section 206—vegetation community adaptive management. Engineer Research and Development Center (U.S.), September 2023. http://dx.doi.org/10.21079/11681/47559.

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As part of the US Army Corps of Engineers (USACE) Continuing Authorities Program (CAP), Section 206 projects focus on restoring aquatic habitats for the benefit of fish and other wildlife. From 2017–2021, USACE Engineer Research and Development Center–Environmental Laboratory researchers in the Aquatic Ecology and Invasive Species Branch (ERDC-EL EEA) at the Lewisville Aquatic Ecosystem Research Facility (LAERF) collaborated with USACE Galveston District, The Nature Conservancy, US Fish and Wildlife Service, National Park Service, and local nonfederal sponsors—Brownsville (Texas) Public Utility Board and the City of Brownsville—to study restoration methods on former, naturally cut-off, channels of the Lower Rio Grande River. These aquatic ecosystems, locally termed “resacas,” are home to endemic plants and animals and are thus an important natural resource of national interest. This technical report documents the planning, design, construction, monitoring, and adaptive management activities throughout the Resaca Boulevard Resaca Section 206 Aquatic Ecosystem Restoration project. Methods and results for invasive species management—primarily Brazilian peppertree (Schinus terebinthfolia)—and aquatic and riparian vegetation establishment in endemic Texas ebony resaca forest, subtropical Texas palmetto woodland, and Texas ebony/snake-eyes shrubland habitats are discussed.
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Dick, Gary O., R. M. Smart und Lynde L. Dodd. Propagation and Establishment of Native Plants for Vegetative Restoration of Aquatic Ecosystems. Fort Belvoir, VA: Defense Technical Information Center, Juni 2013. http://dx.doi.org/10.21236/ada582960.

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Gosink, Luke, Vanessa Bailey, Jerry Tagestad und Katherine EO Todd-Brown. Monitoring of Terrestrial Aquatic Ecosystems Through Analysis of Time-Variant Hyperspectral Imagery. Office of Scientific and Technical Information (OSTI), Dezember 2020. http://dx.doi.org/10.2172/1989211.

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