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Modellstudie av föroreningsretention i Bäckaslövs våtmark : Tillämpning av modellverktygen MIKE SHE WET och MIKE 21Bosson, Emma January 2004 (has links)
During the nineties, ecological handling of urban storm water became very popular in Sweden. Together with Chalmers University of Technology and two Swedish communities, DHI Water and Environment has been doing research of storm water ponds and constructed wetlands. This thesis work is a part of that research project. The work has been applied at the Bäckaslöv storm water treatment plant in Växjö, Sweden. The plant consists of one storm water pond and a downstream constructed wetland. Simulations in two different modelling programs, MIKE SHE WET and MIKE 21 have been performed. MIKE SHE WET has never been used in practical work. The purpose of the program is to describe chemical and biological processes in wetlands and how the plants affect the retention of nutrients in the water. Since the program never has been used before, the main work has been to test the model to investigate whether it fulfil its purpose or not. MIKE 21 has been used to describe how the geometry influences the retention of suspended material, nitrogen and phosphorus. MIKE 21 has also been used to study how the wetland works without the storm water pond. To be able to describe the natural processes going on in wetlands the program MIKE SHE WET has to be further developed. The work has yet resulted in a package of measures that can improve the model. Science is in need for a model like MIKE SHE WET. If the program will be edited it can contribute a lot to the research of wetlands and storm water treatment. The simulations in MIKE 21 show that today’s shape of the wetland is not most favourable. If the water was spread over a bigger area the retention of nitrogen, phosphorus and suspended material would increase. / Anläggandet av konstgjorda våtmarker och sedimenteringsdammar har varit intensivt under nittiotalet och ekologisk dagvattenhantering har blivit mycket populärt i Sveriges kommuner. DHI Water and Environment bedriver i samarbete med Chalmers tekniska Högskola samt Växjö och Örebro kommuner ett forskningsprojekt kring anlagda dammar och våtmarker. Meningen är att resultaten ska kunna användas vid såväl uppföljningsarbete av befintliga dammar samt vid anläggandet av nya dagvattenanläggningar. Detta examensarbete ingår som en del av ovan nämnda forskningsprojekt. Arbetet har tillämpats på Bäckaslövs dagvattenanläggning i Växjö. Anläggningen består av en sedimenteringsdamm med efterföljande våtmark. Modellstudier har utförts i två olika modellprogram, MIKE SHE WET och MIKE 21. MIKE SHE WET har inte tidigare använts i praktiken och har därför testats för att undersöka om programmet uppfyller sitt syfte. Programmet har utformats för att kunna simulera växternas påverkan på kväve- och fosforretentionen. Med hjälp av MIKE 21 har simuleringar utförts för att undersöka hur våtmarkens geometri kan förändras för att få en optimerad avskiljning av kväve, fosfor och suspenderat material. Simuleringar har också utförts för att undersöka hur våtmarken skulle fungera utan uppströms liggande sedimenteringsdamm. Resultaten visar på att MIKE SHE WET måste vidareutvecklas för att kunna beskriva de biologiska och kemiska processer som pågår i våtmarken. Arbetet har lett fram till ett antal konkreta åtgärdsförslag för att förbättra programmet och modellen har potential att bli ett viktigt hjälpmedel i framtida forskning kring våtmarker. MIKE 21-simuleringarna har visat mycket goda resultat. Resultaten visar på att våtmarken idag inte har optimal utformning för att kunna rena det dagvatten som flödar in i den. Om våtmarken utformas så att vattnet får en större spridning i området kommer reningen av såväl suspenderat material som kväve och fosfor att förbättras.
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CONSTRUCTED WETLANDS FOR WASTEWATER REUSE AND ECOSYSTEM REHABILITATION OF THE IRAQI MARSHLANDS : - The case of the small city of Al-Chibayish in Thi-Qar Province, IraqHassan, Ali Tahir January 2010 (has links)
The risk of the Iraq’s marshlands disappearing is still high unless serious measures are adopted. Sewage discharge and irrigation-water pressure, compounded by the effects of climate changes and the extent of the planned dam construction in upstream countries, make this event more likely. Most of the marshlands’ inhabitants (Marsh Arabs) are suffering from lack of access to safe, clean water and lack of sanitation and are reluctant to look for better places to live and work. Constructed wetlands are among the best alternatives to solve their problems. The application of constructed wetlands to meet more stringent standards for wastewater reuse in agriculture contributes to mitigating the wastewater impact and irrigation pressure on the marshland ecosystem. It is here proposed that a 3.6 ha free-surface flow wetland could manage the more stringent standard for reuse (15 mg/l) for BOD5 and TSS. A monitoring programme should nevertheless be associated with this kind of project to minimize health risks that may arise as a result of implementation. Despite the absence of studies that deal with wastewater reuse in irrigation projects at the national level (in Iraq), similar studies worldwide provide evidence of reuse possibilities. Furthermore, a performance requirements framework for wastewater reuse in irrigation projects such as the one suggested by Biswas, draws an approach to meet sustainable development indicators and would likely contribute to support and encourage the Marsh Arabs to settle back in their own areas.
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Implementation of a GIS to Assess the Effects of Water Level Fluctuations on the Wetland Complex at Long Point, OntarioHebb, Andrea January 2003 (has links)
The Long Point wetland complex is one of the most significant coastal wetland systems in the Great Lakes, containing a diverse mosaic of wetland vegetation communities that have developed in response to water level fluctuations due to natural climate variability. Natural short-term water level variations are important for promoting wetland productivity and diversity, but long-term water level changes resulting from human-induced climate change can have serious and long-term consequences on the integrity and health of wetlands. The historical response of the wetland to water level fluctuations was quantified and modelled to provide an indication of how the wetland may respond to future projected water level changes - water level fluctuations are used as a surrogate for climate change.
A spatiotemporal trend analysis was conducted within a geographic information system (GIS) to determine the effects of water level conditions on wetland vegetation and land cover at the wetland complex at Long Point, Ontario for seven years from 1945 to 1999. The spatiotemporal trend analysis documented changes in the structure and composition of the wetland complex in response to declining and rising water level conditions. During drier periods, there were significant increases in the amount of drier emergent and meadow vegetation, especially within the Inner Bay and northern portion of the outer peninsula. There was less fragmentation and complexity in the wetland as these drier communities expanded forming larger continuous patches of vegetation. During wetter periods, open water increased and there was a predominance of wetter emergent and meadow communities in the wetland. Drier vegetation communities became interspersed with water creating a more fragmented convoluted wetland landscape.
The historical response of the wetland vegetation and land cover to water level fluctuations was then simulated with three different wetland models developed in the GIS. A rule-based model, a probability model, and a transition model were developed to assess wetland response to future water level changes. The models were evaluated using simple statistical methods. The transition and rule-based models performed the best and were successful in predicting over 80 % of the wetland vegetation distribution correctly. The probability model was the least successful, predicting only 55 % of the response correctly.
The GIS proved successful in documenting wetland response to historical water level fluctuations and providing insight into the potential impacts of future climate change though water level fluctuations on the Long Point coastal wetland complex. The spatiotemporal analysis and wetland modelling advance the role of GIS in wetland management and analysis. They are practical methods within a GIS that can be used to assess the impacts of climate change on wetland systems and to document and model wetland change in other coastal wetlands of the Great Lakes.
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Nitrate sources and cycling at the Turkey Lakes Watershed: A stable isotope approachSpoelstra, John January 2004 (has links)
<p class=MsoNormal><span style="mso-spacerun: yes"> </span>Stable isotopic analysis of nitrate (<sup>15</sup>N/<sup>14</sup>N and <sup>18</sup>O/<sup>16</sup>O) was used to trace nitrate sources and cycling under undisturbed conditions and following harvest at the Turkey Lakes Watershed (TLW), located near Sault Ste. Marie, Ontario, Canada. <span style="mso-spacerun: yes"> </span>
<p class=MsoNormal><span style="mso-spacerun: yes"> </span><span style="mso-spacerun: yes"> </span>Bulk precipitation collected biweekly at the TLW from 1995 to 2000 had nitrate isotope values that ranged from +42. 4 to +80. 4‰ for <span style='font-family:Symbol'>d</span><sup>18</sup>O and -6. 3 to +2. 8‰ for <span style='font-family:Symbol'>d</span><sup>15</sup>N. <span style="mso-spacerun: yes"> </span>An incubation experiment indicated that the isotopic composition of atmospheric nitrate was not compromised by collection methods whereby unfiltered bulk precipitation samples remain in the collector for up to two weeks. <span style="mso-spacerun: yes"> </span>
<p class=MsoNormal><span style="mso-spacerun: yes"> </span>The first direct measurement of the isotopic composition of microbial nitrate produced <i>in situ</i> was obtained by eliminating precipitation inputs to three forest floor lysimeters and subsequently watering the area with a nitrate-free solution. <span style="mso-spacerun: yes"> </span>Microbial nitrate had <span style='font-family:Symbol'>d</span><sup>18</sup>O values that ranged from +3. 1 to +10. 1‰ with a mean value of +5. 2‰, only slightly higher than values predicted based on the <span style='font-family:Symbol'>d</span><sup>18</sup>O-H<sub>2</sub>O of the watering solution used. <span style="mso-spacerun: yes"> </span><span style='font-family:Symbol'>d</span><sup>18</sup>O values of soil O<sub>2</sub> (+23. 2 to +24. 1‰) down to a depth of 55cm were not significantly different from atmospheric O<sub>2</sub> (+23. 5‰) and therefore respiratory enrichment of soil O<sub>2</sub> did not affect the <span style='font-family:Symbol'>d</span><sup>18</sup>O values of microbial nitrate produced at the TLW. <span style="mso-spacerun: yes"> </span>
<p class=MsoNormal><span style="mso-spacerun: yes"> </span>Nitrate export from two undisturbed first-order stream basins was dominated by microbial nitrate, with the contribution of atmospheric nitrate peaking at about 30% during snowmelt. <span style="mso-spacerun: yes"> </span>Clear-cutting of catchment 31 in 1997 resulted in elevated nitrate concentrations, reaching levels that exceeded the drinking water limit of 10 mg N/L. <span style="mso-spacerun: yes"> </span>Isotopic analysis indicated that the source of this nitrate was predominantly chemolithoautotrophic nitrification. <span style="mso-spacerun: yes"> </span>The <span style='font-family:Symbol'>d</span><sup>18</sup>O values of microbial nitrate in stream 31 progressively increased during the post-harvest period due to an increase in the proportion of nitrification that occurred in the summer months. <span style="mso-spacerun: yes"> </span>Despite drastic alteration of nitrogen cycling in the catchment by the harvest, <span style='font-family:Symbol'>d</span><sup>15</sup>N-nitrate values in shallow groundwater did not change from the pre-harvest. <span style="mso-spacerun: yes"> </span>Denitrification and plant uptake of nitrate in a small forested swamp in catchment 31 attenuated 65 to 100% of surface water nitrate inputs following harvest, reducing catchment-scale nitrate export by 35 to 80%.
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Bio-economic considerations for wetland policy on an agricultural landscapeCuddington, Amber Dawne 26 May 2008 (has links)
This study looks at land use allocation and wetland management on an agricultural landscape in the Canadas Prairie Pothole Region (PPR) within the context of social, ecological and economic factors. Policy considerations for the conservation of wetlands on an agricultural landscape are examined with a focus on financial incentive-based policy tools. Empirical research looks at the influences on wetland management and the potential for economic incentives in wetland policy. In addition, a spatial approach was employed to develop specific wetland conservation targeting scenarios for two case study farms in two distinct agricultural regions of Saskatchewan. Each targeting scenario was investigated to determine the potential effect on ecological goods and services, particularly carbon sequestration, as well as farm income over time. A hypothetical financial incentive-based wetland conservation program was developed looking at the potential of interplay with private carbon markets.<p>Land productivity, which is directly related to farm profitability, was the most important factor in predicting farmer participation in wetland conservation voluntarily (P<0.05). However, participation in the Environmental Farm Plan program, which provides financial incentives, was influenced by demographic factors such as age and farm size (P<0.01) while land productivity had no influence. This indicates that financial incentives may encourage farmers to participate in wetland conservation practices that otherwise would not. The spatial targeting scenarios indicated that trade-offs exist between economic and ecological optimization, the most effective strategies have the highest level of benefits relative to costs and will be readily adopted by farmers. Results also indicate that the publicly funded portion of wetland conservation program payments can be reduced by up to 20% when there is interplay with private carbon markets.
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Shallow soil moisture - ground thaw interactions and controlsGuan, Xiu Juan (May) 19 January 2010 (has links)
Soil moisture and ground thaw state are both indicative of a hillslopes ability to transfer water. In cold regions in particular, it is widely known that the wetness of surface soils and depth of ground thaw are important for runoff generation, but the diversity of interactions between surface soil moisture and ground thaw themselves has not been studied. To fill this knowledge gap, detailed shallow soil moisture and thaw depth surveys were conducted along systematic grids at the Baker Creek Basin, Northwest Territories. Multiple hillslopes were studied to determine how the interactions differed along a spectrum of topological, typological and topographic situations (T³ template). Results did not show a simple relationship between soil moisture and ground thaw as was expected. Instead, correlation was a function of wetness such that the correlation between soil moisture and ground thaw improved with site wetness. To understand why differences in soil moisture and ground thaw state arose, water and energy fluxes were examined for these subarctic study sites to discern the key processes controlling the patterns observed. Results showed that the key control in variable soil moisture and frost table interactions among the sites was the presence of surface water. At the peatland and wetland sites, accumulated water in depressions and flow paths maintained soil moisture for a longer duration than at the hummock tops. These wet areas were often locations of deepest thaw depth due to the transfer of latent heat accompanying lateral surface runoff. Although the peatland and wetland sites had large inundation extents, modified Péclet numbers indicated that the relative influence of external and internal hydrological processes at each site were different. Continuous inflow from an upstream lake into the wetland site caused advective and conductive thermal energies to be of equal importance to ground thaw. The absence of continuous surface flow at the peatland and valley sites led to the dominance of conductive thermal energy over advective energy for ground thaw. A quantitative explanation for the shallow soil moisture-ground thaw patterns was provided by linking hydrological processes and hillslope storage capacity with the calculated water and energy fluxes as well as the modified Péclet number. These results suggest that the T³ template and the modified Péclet number could be very useful parameters for differentiating landscape components in modeling soil moisture and frost table heterogeneity in cold regions.
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Water Storage Capacity and Flow Dynamics in a Papyrus Wetland, Uganda : Implications for Studies of Water Treatment EffectsAsp, Karl January 2009 (has links)
<!--[if !mso]> <object classid="clsid:38481807-CA0E-42D2-BF39-B33AF135CC4D" id=ieooui></object><mce:style><! st1\:*{behavior:url(#ieooui) } --> Hydrological investigations were performed in the Lubigi papyrus wetland in suburban Kampala, Uganda, impacted by human encroachment for settlement and agriculture. The first aim was to investigate the water flow variations and the dampening effect of the wetland. A second aim was to estimate the effective wetland volume and area, and relate this to the wetland function for treatment of the suburban runoff. A study site with well defined inflows and outflows was chosen, and three transects were cut through the papyrus to be able to study the water movement beneath the floating papyrus mat. Water flow measurements showed a flow dampening effect of the wetland on peak flows after rains, and the water balance revealed that the precipitation on the wetland was only 4 % of the inflow during the study. The tracer added at the inlet was rapidly detected downstream in the canal in the middle of the wetland, indicating a strong short-circuiting effect of the human made canal. At the outlet the tracer concentration was lower than the detection limit, suggesting a good mixing in the downstream part of the wetland, which was also supported by other water quality measurements in the transects. Ammonium-N concentrations at the inflow and outflow indicated a net export of ammonium-N, but the observed flow variations suggest that intensive water sampling campaigns are necessary for a proper evaluation of the water treatment function. The calculated effective volume and area amounted to 74 and 46 %, respectively, of the theoretically estimated, with a corresponding loss in the flow dampening and water treatment function of the wetland. / Rapporten är ett resultat av ett Minor Field Study stipendium finansierad av Sida.
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Long term assessment of created wetlands functioning within agricultural areasDantas Mendes, Lipe Renato January 2012 (has links)
The polluted agricultural wastewater, after reaching marine recipients, can cause eutrophication. This problem can be tackled and mitigated by using constructed wetlands as water treatment systems. The fact that constructed wetlands work through long periods of time has led many scientists to evaluate how long they can still treat their influents effectively. The development and growth of vegetation and the accumulation of nutrients on the soils in a wetland are expected to occur. These processes change the wetland efficiency to remove pollutants. In this study, a set of wetlands constructed to treat agricultural wastewater were analyzed in different periods to assess if there is a difference in removal efficiency of nitrogen and phosphorus. This assessment was performed by analyzing the retention rate, k and k20 values, which are variables that quantify the nutrients removal, in different periods of each employed wetland. Some of the observations demonstrated differences when comparing different periods of the wetlands. The nitrogen removal presented better performance in one of the employed wetlands when this was older. Another employed wetland has not shown a clear difference between different periods. In the wetlands with high vegetation densities, the nitrogen removal was more stable over consecutive years. The occurrence of oscillations in nitrogen removal was observed more often in the wetlands with the highest vegetation densities over consecutive years. The phosphorus removal presented no clear differences between different periods. The results suggest that the removal of nitrogen improves after wetland creation due to the growth of vegetation. In addition, they suggest that wetlands with high vegetation densities tend to oscillate the nitrogen removal more or less often according to the density of the vegetation due to the balance between denitrification and decomposition. Further, the results suggest that the removal of phosphorus remains unchanged over longer periods than the periods considered in this study (four to six years) due to the deposition of organic matter on the soils.
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Catchment factors affecting particle and phosphorus retention in constructed wetlands receiving agricultural runoffSenior, Anna January 2012 (has links)
Eight agricultural catchments in south Sweden were investigated for factors that may affect phosphorus (P) load and retention in the downstream situated wetlands (WL). P load is known to affect retention, and is determined by hydrological and geographical catchment characteristics. The wetlands were small (0.02-0.88%) in relation to their catchments (CA) and varied in design. Net sedimentation and P retention was determined with sedimentation plates during one year. The variables that best explained differences in particles and TP retention were the hydraulic load (q), TP load and the wetland length to width ratio. Contrary to expectations there was no correlation between factors that could be associated with erosion (i.e. slope and soil clay content) and retention of neither particles nor TP. Generally, the highest amounts of settled particles and P were found close to the wetland inlets, but soil disturbance (i.e. tillage) and high q increased the settling distance. It was likely that the smallest clay particles were too unaggregated to settle within these wetlands. Factors not included, such as wetland vegetation and bioturbation may have a large impact on P retention and this should be further investigated. The study also points to the difficulties in scaling down geological and P loss data from a regional to a local scale, as there can be large local deviations from the regional standard values. An easy method for identification of local “hotspots” for P losses should be of value for planning the location of future wetlands.
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An evaluation of the potential of coastal wetlands for hurricane surge and wave energy reductionLoder, Nicholas Mason 15 May 2009 (has links)
Given the past history and future risk of storm surge in the United States,
alternative storm protection techniques are needed to protect vital sectors of the
economy and population, particularly within southeastern Louisiana. It is widely
hypothesized that coastal wetlands offer protection from storm surge and wave action,
though the extent of this protection is unknown due to the complex physics behind
vegetated flow dynamics. This thesis presents numerical modeling results that estimate
the relative sensitivity of waves and storm surge to characteristics embodied by coastal
wetlands. An idealized grid domain and 400 km2 (20 km by 20 km) marsh feature
provide a controlled environment for evaluating marsh characteristics, including bottom
friction, elevation, and continuity. Marsh continuity is defined as the ratio of healthy
marsh area to open water area within the total wetland area.
It is determined that increased bottom friction reduces storm surge levels and
wave heights. Through the roughening of the bottom from sandy to covered with tall
grass, it is estimated that waves may be dampened by up to 1.2 m at the coast, and peak
surge may be reduced by as much as 35%. The lowering of marsh elevation generally increases wave heights and decreases surge levels, as expected. A 3.5 m decrease in
marsh elevation results in as much as a 2.6 m increase in wave height, and up to a 15%
decrease in surge levels. Reductions in marsh continuity enhance surge conveyance into
and out of the marsh. For storms of low surge potential, surge is increased by as much
as 70% at the coast due to decreasing marsh continuity from 100% to 50%, while for
storms of high surge potential, surge is decreased by 5%. This indicates that for storms
of high surge potential, a segmented marsh may offer comparable surge protection to
that of a continuous marsh. Wave heights are generally increased within the marsh due
to the transmission of wave energy through marsh channels. Results presented in this
thesis may assist in the justification of coastal wetland mitigation, and optimize marsh
restoration in terms of providing maximum storm protection.
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