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31	Processus hydrodynamiques et de rétention dans le transfert des pesticides dans la zone non saturée : Epérimentations et modélisations avec le glyphosate, le S-métolachlore et leurs métabolites dans les solides fluvio-glaciaires de l'Est lyonnais / Hydrodynamic and retention processes in pesticide transfer in the vadose zone : Experiments and modelling of glyphosate, S-metolachlor and their metabolites transfer in glaciofluvial solids of the East of Lyon Sidoli, Pauline 27 June 2016 (has links) La zone non saturée joue un rôle clé sur le transfert des pesticides et la qualité des eaux souterraines. Les connaissances sur les processus d’écoulement et de rétention dans les matériaux géologiques de la zone non saturée au-delà des sols sont toutefois parcellaires. Le transfert du glyphosate et du S-métolachlore (SMOC), et de leurs métabolites AMPA, ESA-métolachlore (MESA) et OXA-métolachlore (MOXA) est étudié en colonne pour deux matériaux fluvio-glaciaires issus d’un aquifère de l’Est lyonnais : un sable, S-x, et un mélange bimodal de graviers et de sables, Gcm,b. Pour des conditions de non-saturation en eau, l’écoulement dans les colonnes est fractionné en deux zones, eau mobile et eau immobile, d’importance variable suivant le solide. La sortie du SMOC est retardée par rapport au traceur de l’eau ; son bilan de masse déficitaire traduit une rétention de la molécule lors de son transfert. A l’inverse, le MESA et le MOXA se comportent comme le traceur de l’eau. Le glyphosate et l’AMPA sont très peu mobiles dans la colonne de Gcm,b (seul matériau étudié) avec des quantités éluées inférieures à 1% de la quantité appliquée. La modélisation montre que le transfert des molécules est affecté de manière variable suivant le matériau par la cinétique physique d’échange entre les zones d’eau mobile et immobile et par la cinétique chimique des molécules. Cette cinétique chimique est décrite par des expérimentations complémentaires de sorption en batch. La caractérisation des matériaux révèle la présence d’oxydes et de minéraux argileux qui pourrait expliquer leur forte réactivité, qui s’avère parfois supérieure à celle des sols de la zone d’étude. / Vadose zone play a key role in pesticides transfer and groundwater quality. Knowledge’s about leaching and retention processes in the vadose zone below the shallow soil zone are still poorly understood. Transfer of glyphosate, S-metolachlor (SMOC), and their metabolites AMPA, ESA-metolachlor (MESA) and OXA-metolachlor (MOXA) is studied in unsaturated columns filled with two glaciofluvial materials collected in the East of Lyon: a sand, S-x, and a bimodal gravel, Gcm,b. Experiments show water fractionation into mobile and immobile compartments with variable importance according to material column. SMOC outflow is delayed compared to the conservative tracer. SMOC mass balance is in deficit revealing retention in columns. At the opposite, complete mass elution associated with retardation factors close to unity shows that there is no adsorption of MESA and MOXA in either lithofacies. Glyphosate and AMPA mobility is very low in the one Gcm,b column studied with amounts in leachates inferior to 1% of applied. Modelling show pesticides and metabolites transfer is affected by both flow regionalisation and non-equilibrium sorption. Chemical kinetic of sorption mechanisms is studied with complementary batch experiments. The high glaciofluvial materials reactivity, in some cases upper than soil reactivity from the study site, could be attributed to oxides and clay minerals. Pesticides Zone non saturée Transfert Eaux souterraines Pesticides Vadose zone Leaching Groundwater
32	Hydraulic properties of the vadose zone at two typical sites in the Western Cape for the assessment of groundwater vulnerabilitv to pollution Samuels, Donovan January 2007 (has links) >Magister Scientiae - MSc / Aquifer vulnerability assessment is increasingly becoming a very significant basis in order to fulfil the water demands in South Africa. Knowledge of soil hydraulic properties that consists of the soil water retention and hydraulic conductivity functions is a prerequisite for predicting solution transport in soils. The overall objective of the study is to develop a database of hydraulic properties for collected undisturbed samples and to test selected models by making use of this database. Studies of the vadose zone are generally restricted to the top 1.2 meters; therefore this study aims at essentially improving the lack of measurements and modelling in the vadose zone. There exist several methods to determine hydraulic properties of soil that make use of hydraulic conductivity (K) determination in the vadose zone. The most accurate estimates of hydraulic conductivity are possible through direct measurements or measurements of the water retention curve. For this study, the drilling and sampling of five boreholes (maximum depth 20 m) proceeded during March and April 2005 at two typical sites in the Western Cape, namely the Berg river site (Riebeek West) and Ithemba site (Cape Flats). In total, 76 undisturbed core samples were collected from which the detailed borehole log descriptions were made. The determination of the soil water retention curves of the collected samples was based on laboratory techniques using Eijkelkamp drying and suction equipment (sand box and clay box). When modelling groundwater vulnerability, it is essential to look at the soil water retention curves with increased importance, as they provide graphical and mathematical confirmation of porosity, preferential flows, volumetric water content and unsaturated hydraulic conductivity. Therefore, a numerical model called RETC was used to determine soil hydraulic properties. The RETC model uses equations of Van Genuchten (Van Genuchten, 1980) and Brooks-Corey (Brooks and Corey, 1966) to determine parameters for soil water retention and the methods of Mualem (1976) and Burdine (1953) to determine unsaturated hydraulic conductivity functions. Saturated hydraulic conductivity values were estimated by using RETC soil database based on textural descriptions of collected samples. Using the soil hydraulic estimates obtained from RETC, sensitivity analyses were run with a one dimensional transport model, Macro 5.0 for two sites at iThemba and in the Berg river. Groundwater vulnerability Hydraulic properties MACRO 5.0 RETC Soil water retention curve Vadose zone
33	Characterization of the Uranium-Bearing Phases Produced by Novel Remediation Technologies for Sequestration of Mobile Radiological Contaminants in the Hanford 200 Area Vadose Zone Lapierre, Robert Michael 19 July 2018 (has links) Of the many toxic chemicals released into the Hanford vadose zone over the decades of nuclear weapons production, uranium has emerged as a contaminant of significant interest. The ammonia gas injection remediation method has been identified as a promising approach towards mitigating the risks to the ecosystem by limiting the mobility of the radionuclide in the vadose zone. The remediation method was replicated using synthetic porewater solutions with a range of constituent concentrations equal to that of the Hanford 200 Area vadose zone. The uranium-bearing products of the remediation method were characterized using kinetic phosphorescence analysis for aqueous uranium, scanning electron microscopy with energy dispersive spectroscopy and electron microprobe for imaging and elemental analysis, and a sequential extraction procedure modified for the sample precipitates. Evaluation revealed that the resultant uranium-bearing solids likely took the form of uranium-silicates and uranium carbonates, with the latter being precipitated primarily in mid-to-high bicarbonate samples. Uranium Remediation Ammonia Hanford Vadose Zone Analytical Chemistry Earth Sciences Environmental Chemistry
34	Water cycling on cultivated land: an investigation of hydrological separation in the vadose zone Smith, Devin Foster 29 August 2019 (has links) No description available. Earth Hydrology Soil Sciences
35	Analysis of the impact of anthropogenic pollution on shallow groundwater in peri-urban Kampala Kulabako, Robinah January 2005 (has links) An investigation to assess the anthropogenic pollutant loads, transport and impact on shallow groundwater in one of Kampala’s peri-urban areas (Bwaise III Parish) was undertaken. Bwaise III is a densely populated informal settlement with a high water table (<1.5 m) and inadequate basic social services infrastructure (e.g, sanitation, safe water supply, roads, etc). Field surveys were undertaken to identify, locate and quantify various pollutant sources. Information on the usability and operational aspects of the excreta and solid waste management systems was obtained from consultations with the residents. Water from installed monitoring wells and one operational protected spring and wastewater (sullage) characteristics (quality, discharges for drains and spring, water levels for the wells) as well as soil characteristics (soil stratigraphy, physical and chemical) were determined through field and laboratory measurements. Laboratory batch experiments were undertaken to estimate phosphorus sorption potential of the soils. The results reveal that excreta disposal systems, solid waste and sullage are the major contributors to shallow groundwater contamination. High contaminant loads from these sources accumulate within the area resulting in widespread contamination. The water table responds rapidly to short rains (48hr) due to the pervious and shallow (<1 m) vadose zone, which consists of mostly organic fill material. Rapid water quality deterioration (increased thermotolerant coliforms, organic content in the form of total kjedahl nitrogen, phosphorus) following rains potentially follows from leaching, desorption and macropore flow. Spatial variation of the water quality in the area is largely related to anthropogenic activities within the vicinity of the well sources. Animal rearing, solid waste dumps and latrines are seen to result in increased localised microbial and organic content during the rains. The spring discharge with high nitrate levels does not respond to short rains suggesting that this source is fed by regional baseflow. The corresponding high microbial contamination in this case is a result of observed poor maintenance of the protection structure leading to direct ingress of contaminated surface runoff. Natural attenuation of contaminants is very limited. Estimated bacteria die-off rates are very low, about 0.01hr-1, suggesting a high risk for microbial contamination. The soils still have potential to retain additional phosphorus, whose sorption is largely a function of iron, available phosphorus and moisture content of the soils. This is also seen with the model results in which the phosphorus contaminant plume sticks to the surface irrespective of the rainfall infiltration rates. Simulation results show that continuous heavy intense rains (> 0.25mm/min) result in rapid flooding occurring within 1hr to 2 days. With lower rains, the water table does not rise to the surface, and no flooding takes place. Protection of the shallow groundwater in the area requires socio-technical measures targeting reduction of pollutant loads within the area as well as a wider spring catchment. Re-protection of the spring, coupled with awareness creation, should be immediately addressed so as to reduce microbial contamination. Community participation in solidwaste management should be encouraged. Resource recovery systems such as composting of the mostly organic waste and use of ecological sanitation toilet systems should be piloted in the area. Successful operation of the systems however depends on continuous sensitisation of the communities. / QC 20101207 Shallow groundwater Sanitation Peri-urban Vadose zone Anthropogenic Modelling Other Environmental Engineering Annan naturresursteknik
36	Complex network theoretical approach to investigate the interdependence between factors affecting subsurface radionuclide migration Narayanan, Brinda Lakshmi January 2022 (has links) Mining of uranium ore and its extraction using the milling process generates solid and liquid waste, commonly termed uranium mine tailings. Uranium mine tailings is radioactive, as it consists of residual uranium, thorium, and radium, which amounts to 85% of the original ore’s radioactivity. Due to the extensively long half-lives of uranium (4.5x109 years), thorium (75,400 years), and radium (1,620 years) and their harmful radioactive, it is imperative to isolate uranium mine tailings from the environment for a longer period. Containment of uranium mine tailings in dam-like structures, called uranium mine tailings dam (UMTD), is the most followed disposal and storage method. Like a conventional water retention dam, UMTDs are also susceptible to failure, mainly due to adverse weather conditions. Once the UMTD fails, a fraction of the radioactive tailings infiltrates and migrate through the vadose zone contaminating the groundwater sources underlying it. Radionuclide behavior and migration in the subsurface are affected by several environmental factors. To minimize the uncertainty and improve current radionuclide fate and transport models, it is vital to study these factors and any interdependence existing between them. This study aims to understand these environmental factors by i) enlisting the factors affecting subsurface radionuclide migration through scoping review of articles and reports, and ii) analyzing the interdependence existing between the factors using the complex network theory (CNT) approach and identifying the dominant factors among them. Factors such as chemical and biological characteristics of soil stratigraphy, groundwater, and radioactive tailings plume, meteorological, and hydrogeological are found to influence radionuclide behavior and transport mechanisms in the vadose zone. CNT approach described soil microorganisms, fraction of organic carbon, infiltration rate of the soil, transmissivity, clay fraction in the soil, particulates in groundwater, and infiltrating rainwater as dominant factors in the NoF based on their centrality measures and sensitivity analysis of the network of factors (NoF). Any uncertainty associated with these factors will affect and propagate through the model. Hence, sufficient resources should be directed in the future to characterize these factors and minimize their uncertainty, which will lead to developing reliable fate and transport models for radionuclides. / Thesis / Master of Applied Science (MASc) / Waste products from uranium mining and milling operations are called uranium mine tailings, which are radioactive. Generally, uranium mine tailings are disposed of and isolated in dam-like structures referred to as uranium mine tailings dams (UMTD). One of the most common causes of UMTD failure is extreme weather conditions. When a UMTD fails, a part of tailings, consisting of radionuclides uranium, thorium, and radium, infiltrate into the subsurface through the vadose zone. Radionuclide behavior and transport in the subsurface is influenced by several environmental factors. The objective of the present study is to understand the factors affecting radionuclide migration by i) conducting a scoping review on radionuclide migration in the subsurface to describe the factors studied in the literature, and ii) understanding and analyzing any relation among the factors and deriving the most dominant factors based on their relation. This study can be used further to develop accurate and reliable radionuclide fate and transport models with minimal uncertainty. Complex network theory interdependent factors centrality sensitivity analysis radionuclides vadose zone
37	<b>DIRECT IN SITU MEASUREMENT OF PFAS LEACHING AT A LONG-TERM LAND-APPLIED BIOSOLIDS SITE</b> Jamie Ellen Klamerus (18423201) 22 April 2024 (has links) <p dir="ltr">Per- and polyfluoroalkyl substances (PFAS) are a group of synthetic chemicals known for their persistence in the environment and potential health risks. PFAS are linked to several adverse effects in human and wildlife health. The detection of PFAS in biosolids has raised concerns about their use in agricultural and land application practices. This is because some PFAS are known to enter the food system through plant uptake and some leach into groundwater. The purpose of this study was to examine the PFAS profile in soils and porewater with depth at an agricultural site with historical biosolids applications. The site selected has received biosolids at agronomic rates for corn for approximately four decades. This study utilized a total of six lysimeters, three “shallow” at 60 cm and three “deep” at 120 cm, to monitor PFAS leaching in soil. Porewater samples were collected within 1-3 days after rain events based on rainfall amount and response of the moisture sensor installed at the site. For each of five porewater sampling events, PFAS and supplemental water parameters like total organic carbon (TOC) and pH were measured. Soil cores, taken in one-foot increments before and after the 3-month study, were analyzed for PFAS, soil OC, moisture, and grain size. All samples were analyzed using high resolution mass spectrometry for 54 PFAS and in line with EPA 1633 method. Soil characteristics such as texture, moisture, and soil OC significantly influence PFAS transport and sorption capacity within the soil profile, impacting PFAS distribution across soil depths. PFAS in the soil profile decreased with increasing depth and directly correlated with soil OC. Long chain PFAS were strongly retained in the top 60 cm and minimally distributed to the porewater. Short-chain PFAS proportionally dominated porewater samples, with elevated concentrations observed in shallow porewater driven by increased saturation (perched water) from a low permeability clay layer. Unsaturated conditions enhance PFAS retardation through air-water interface partitioning in addition to soil particle sorption mechanisms. In this study, less than 0.1% of PFAS leach from the vadose zone of a biosolid impacted plot annually, underscoring the longevity of PFAS in the soil profile and importance of understanding PFAS transport dynamics for effective environmental management.</p> Agronomy Environmental biogeochemistry Land Applied Biosolids PFAS Lysimeter Porewater Vadose zone
38	The Hillslope Hydrology of a Mountain Pasture: The Influence of Subsurface Flow on Nitrate and Ammonium Transport Zegre, Nicolas P. 11 December 2003 (has links) Nonpoint source (NPS) pollution is possibly the greatest form of contamination to our nation's waters. Nutrient pollutants, such as nitrate and ammonium, often enter aquatic ecosystems through surface and subsurface hydrological transport that drain agricultural watersheds. The over-abundance of nitrogen within these watersheds is easily transported to receiving stream and rivers, and result in aquatic ecosystem degradation. In response to the problem of nutrient loading to aquatic ecosystems, ecosystems scientists and federal and state governments have recommended the use of streamside management zones (SMZ) to reduce the amount of NPS pollutants. A small agricultural watershed in southwestern North Carolina was utilized to quantify subsurface transport of nitrate and ammonium to a naturally developing riparian area along Cartoogechaye Creek. Vertical and lateral transport of nitrate and ammonium were measured along three transect perpendicular to the stream. Transects were instrumented with time domain reflectometry (TDR) and porous cup tension lysimeters to monitor soil water and nutrient flux through the pasture and riparian area located at the base of the watershed. The HYDRUS 2-D flow and transport model was used to predict and simulate subsurface flow. Predicted flow was coupled with observed field nutrient data to quantify nutrient flux as a function of slope location. HYDRUS 2-D was capable of simulating subsurface flow (saturated and unsaturated) as a function of observed soil physical properties (bulk density, saturated hydraulic conductivity, particle size distribution, water retention characteristics) and climatic data (precipitation, air temperature, wind speed, etc.). The riparian area was effective in reducing the amount of nonpoint source pollution to a naturally developing riparian area from an agricultural watershed. Dramatic decreases in both NO3- -N and NH4+ -N in upland pasture water were observed within the riparian area. Seasonal percent reductions of NO3- from the pasture to riparian area in subsurface water within the study watershed are as follows: summer (2002) = 456%; fall (2002) = 116%; winter (2003) = 29%; spring = 9%, pasture and riparian, respectively. / Master of Science nutrient transport hydrologic modeling subsurface flow vadose zone hydrology hillslope hydrology riparian zone
39	Preferential flow modelling in a vadose zone using macro 5.0 – Cape flats porous sands and Mpumalanga highveld clays case studies Majola, Kwazikwakhe Alfred January 2008 (has links) Magister Scientiae - MSc / The objectives of this study were: To review and understand flow and transport processes in unsaturated zones. In this study, particular emphasis is placed on understanding mechanisms that cause non-uniform (preferential) flow for two casestudies, namely the Cape Flats sandy environment and the Mpumalanga Highveld fractured rock environment. To evaluate the adequacy of models, in particular MACRO 5.0, in simulating flow and transport in the vadose zone, by making use of two case study sites (Cape Flats and Mpumalanga Highveld). Of particular importance is the evaluation of transfer coefficients to represent fluid and solute exchange between macropores and matrix. To run a sensitivity analysis with MACRO 5.0 in order determine which input model parameters are the most relevant in describing the effects of preferential flow in water and solute transport. Preferential flow Modelling Vadose zone Porous sands Clays Macro 5.0 Cape flats district Mpumalanga highveld (Secunda) Groundwater vulnerability
40	[en] FLUX AND TRANSPORT STUDY OF PURE GASOLINE AND GASOLINE BLENDED ETHANOL IN UNSATURATED POROUS MEDIA / [pt] ESTUDO DO FLUXO E TRANSPORTE DE GASOLINA PURA E MISTURADA COM ETANOL EM MEIOS POROSOS NÃO SATURADOS GUILHERME BARROS DE CASTRO FILHO 19 February 2008 (has links) [pt] O derramamento no solo de poluentes imiscíveis com a água (NAPLs) devido a vazamentos de tanques de armazenamento ou dutos e acidentes de transporte é de grande interesse, pois o NAPL e/ou seus constituintes podem migrar através da zona vadosa até atingir o lençol freático e contaminar as fontes de água potável. No Brasil, a maioria dos postos de combustível e terminais de armazenamento possui tanques de etanol, gasolina misturada com etanol e óleo diesel. Um eventual derramamento ou vazamento de hidrocarbonetos derivados de petróleo, conhecidos como LNAPL, misturados com etanol tem um maior potencial de contaminação em função do efeito de co- solvência. A motivação deste trabalho é que muitos estudos têm sido realizados com principal interesse na zona saturada e pouco se sabe sobre o comportamento destes contaminantes na zona não saturada (McDowell e Powers, 2003 e Österreicher et al., 2007). Portanto, foram realizados ensaios de coluna com esferas de vidro com o objetivo de simular os vazamentos de hidrocarbonetos líquidos na superfície e comparar a massa de benzeno que fica retida no meio poroso em um vazamento de gasolina pura ou com etanol. Para avaliar estes ensaios em uma dimensão foi utilizado um programa disponível no sítio da Agência de Proteção Ambiental dos Estados Unidos (EPA) chamado Hydrocarbon Spill Screening Model (Weaver et al., 1994) e implementado um modelo para efetuar o balanço de massa e considerar o efeito de co-solvência em função da adição de etanol na gasolina comercial brasileira. Os resultados dos ensaios de laboratório foram comparados com os obtidos através do modelo supracitado e apresentaram uma aproximação satisfatória da previsão do comportamento do contaminante. / [en] The subsurface release of water immiscible pollutants (NAPLs) due to leaks in storage tanks or pipelines and spilling transportation accidents is of great concern, since the NAPL or its constituents may migrate through the vadose zone until reaching the water table and eventually contaminate clean water sources. In Brazil, most of the gas stations store ethanol, pure and gasoline blended ethanol, diesel, among others in tanks. A spill or leak of petroleum hydrocarbons, known as LNAPL (light Nonaqueous phase liquid), combined with ethanol has a major contamination potential associated to cosolvency effects. The motivation of this work is that many studies have been developed with special interest in the saturated zone and little is known about the behavior of these pollutants in the vadose zone (McDowell e Powers, 2003 e Österreicher et al., 2007). Thus, one dimensional column tests were performed in a glass porous media to simulate the spill of hydrocarbons in the subsurface and compare the retained mass of benzene in the porous media after a release of a pure or ethanol blended gasoline. In order to evaluate these 1D tests results, the Hydrocarbon Spill Screening Model - HSSM (Weaver et al., 1994) was used. This program can be found in the Environmental Protection Agency (EPA) website. A model was also implemented to consider the cosolvency effects in function of the ethanol addition in Brazilian`s commercial gasoline. The laboratory`s results were compared with the ones obtained by the model mentioned above and showed a satisfactory approximation for the prediction of the contaminant behavior. [pt] SOLO NAO SATURADO [en] UNSATURATED SOIL [pt] GASOLINA [en] GASOLINE [pt] ENSAIO DE COLUNA [en] COLUMN TESTS [pt] ZONA VADOSA [en] VADOSE ZONE

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