Water table | EPFL Graph Search

The water table is the upper surface of the zone of saturation. The zone of saturation is where the pores and fractures of the ground are saturated with water. It can also be simply explained as the depth below which the ground is saturated. The water table is the surface where the water pressure head is equal to the atmospheric pressure (where gauge pressure = 0). It may be visualized as the "surface" of the subsurface materials that are saturated with groundwater in a given vicinity. The groundwater may be from precipitation or from groundwater flowing into the aquifer. In areas with sufficient precipitation, water infiltrates through pore spaces in the soil, passing through the unsaturated zone. At increasing depths, water fills in more of the pore spaces in the soils, until a zone of saturation is reached. Below the water table, in the phreatic zone (zone of saturation), layers of permeable rock that yield groundwater are called aquifers. In less permeable soils, such as tight

Assessment of the water resource in Tambarga (Burkina Faso) based on stable isotope analysis

Tabea Schutter

Assessment of available water is the basis that allows for sustainable management of the water resource. Special need concerns the assessment of groundwater resources, about which, often little is known. The present study aims to explore the water resource, with a focus on groundwater, of a small catchment (3.5km2), situated in a semi-arid zone in Burkina Faso (West Africa). A 5-year data set of stable isotopes of water, groundwater level and other hydrologic data is used to gain insight into the water resources in this small catchment. The main effort is devoted to the analysis of isotope data, with the secondary goal to asses the potential of the use of stable isotopes of water as an innovative tool in hydrology. Analyzed are temporal and spacial variations of the isotopic signature in groundwater, surface water and rain. Isotope data is compared to groundwater level data. Isotope data allowed to distinguish two different categories of wells. First, wells where evaporation dominated compared to recharge at the end of the wet season through the dry season, and wells that have constant isotope ratios throughout the year. Evolution of the isotope signature of the former suggests that these wells get disconnected from the aquifer at some point of the year. Comparison of isotope ratios of different sampling sites (springs, wells, pumps, surface water and rain) revealed that the upstream springs diverge from the other sites in their isotopic signature, and thus either have a different origin or were subject to different processes. Negligible diurnal variations observed in isotopic signatures of wells prompt that diurnal fluctuations observed in groundwater levels are due to non isotope fractionation processes. Periods deduced from seasonal changes in isotopic signatures match periods of rising and decreasing groundwater levels. Though groundwater levels show inter-annual variability, especially in their peak levels, this was not reflected in the isotope data. Isotope data confirmed conclusions gained from other data (recharge periods), added additional information (diurnal fluctuations of wells are non isotope fractionation processes), and pointed out the fact that upstream spring water distinguishes in some form or another from other groundwater.

2014

The effect of seasonal soil frost on the alpine groundwater recharge including climate change aspects

Daniel Bayard

In alpine areas, the snow cover plays an important role as a water reservoir. Water is stored as snow over the winter and released in spring, recharging mountain aquifers through infiltration. These aquifers are essential, especially for supplying water for human activities during dry seasons. Numerous studies have shown that locally soil frost can drastically reduce the water infiltration. However, we know much less about the hydrological impact of soil frost at a larger scale, in particular with regard to groundwater recharge. This was our motivation for initiating an extensive field experiment in the southern Swiss Alps. Several methods at different spatial scales were adapted to explore (a) the local effect of a partially frozen ground on the snowmelt discharge in an alpine area, (b) the key processes influencing groundwater recharge during snowmelt periods, such as snow cover and soil frost evolution, snowmelt water runoff types, (c) the large-scale effect of soil frost on the aquifer recharge, and (d) winter situations that are critical with respect to flooding. In order to take into account spatial, altitudinal and climatic differences, the field study was run for two winter seasons at Gd St Bernard (2500 m), a site with very high winter precipitation and strong winds, and at Hannigalp above Grächen (2100 m), a ski resort with a rather dry winter climate. The different components of the soil water balance (lateral runoff, deep percolation, liquid soil water content) were measured on delimited plots of 5 m2. Additionally, a dye tracer experiment visualized the snowmelt infiltration patterns into the frozen, respectively non-frozen ground. At Gd St Bernard, investigations of the liquid water content and the soil temperature were additionally conducted at two secondary sites, differing in their orientation, so as to gain a better insight of the spatial soil frost expansion. Finally, an analysis of the water-table variation at the village of Grächen (some 500 m below Hannigalp) during the snowmelt was carried out for a 10-year time period, including our experimental seasons. We complemented our field investigations by using a numerical soil-snow-atmosphere transfer model that simulates the seasonal development of the soil frost and the snow cover, as well as lateral and vertical water flow in the top soil. This model was used as an upper boundary condition to a 2-D groundwater model, to calculate the outlet flow at the base of a simplified alpine aquifer. The two winters investigated had contrasting meteorological conditions, which resulted in intriguing differences and similarities with respect to the soil physical conditions: the first one having a thick snowpack and hardly any soil frost, and the second one with hardly any snow until January and a deep and persistent soil frost. In spite of a very thick snowpack, the water balance measurements from winter 2000/2001 showed for both sites zero to low surface and subsurface flow due to the fact that soil frost was local and the soil permeability high. During the next winter, approximately 25% of the total meltwater run off laterally. The soil infiltration capacity was mainly reduced by the presence of a basal ice sheet, caused by the freezing of meltwater after a mid-winter snowmelt event. The field data were used to calibrate and validate a physically-based one-dimensional model. To allow an accurate parameter setting for the water repellent soil of Hannigalp, laboratory infiltration experiments on soil columns were additionally carried out. Using the resultant information, the model predicted correctly most measured soil parameters, in particular good matching was observed between measured and simulated snowmelt discharge. At Gd St Bernard, the simulated results were less satisfactory, especially during the first winter, when large discrepancies were noted between measured and simulated lateral runoff. Apart from the shortage in the soil parameter characterization, the deviation was a result of the simplified description of the experimental field. The model was, for example, not able to simulate surface runoff generated by a steep slope under unfrozen conditions, as the soil surface is considered by the model to be flat. Nevertheless, results were accurate enough to reproduce the occurrences of snowmelt events and the accumulated values of snow-melt discharge pathways under frozen conditions. Long-term weather data were used to simulate the soil frost depth at both sites. The simulation results showed that the probability of the occurrence of frozen soils was lowest on slopes with south or north exposure. On southerly exposed plots, the heat stored in the soil during the summer inhibited the development of deep and persistent soil frost, while most pore ice thawed due to underneath heating. On north plots, the building of soil frost was rare, as early snowfall insulated the ground from the atmosphere. However, during snow-poor winters, the frost penetrated deep into the ground, and the low underneath heat flux at that location hardly affected the frost depth until snowmelt. The snow depth and average soil temperature were hence the two components affecting the frost depth extent. The altitude soil frost variation was related to the spatial extent of these two components. The higher the altitude, the higher the precipitation and the lower the mean air/surface temperature. Simulating the whole Grächen recharge area, seasonal soil frost was rare between 1800 m and 2000 m, as the snowpack was thick enough to insulate the ground, and the soil was warm enough to inhibit deep soil frost. In lower areas, the shallow snowpack enabled the soil to freeze during most winters, whereas at higher areas, deep and persistent soil frost was simulated due to the low underneath heating. A 10-year water-table depth record was used to examine possible large-scale effects of seasonal soil frost. We noted that the water-table rise at snowmelt was lowest at the end of winters with extensive soil frost. However, such winters were characterized by low precipitation, and reduced snow cover. In contrast, winters with little soil frost were mostly snow rich. Consequently, only a reduced number of winters were directly comparable. Considering these winters, the reduction in the water-table rise at snowmelt due to seasonal soil frost varied only between 10 and 30%, as, during snowmelt, most meltwater was able to re-infiltrate into the very permeable ground in lower unfrozen areas. We may assume that a soil with a smaller infiltration capacity can increase the influence of the soil frost on the aquifer recharge. Finally, we investigated the effect of a changing climate on the hydraulic and thermic regimes at different altitudes in the area of Grächen. We assume an increase in the air temperature of 2°C generates deeper soil frost on lower areas, as the resultant smaller snow cover does not insulate the soil from the atmosphere any more. However, it does reduce the soil frost on higher, snow rich areas, due to the warmer air temperature. As a whole, minor changes were simulated on the mean groundwater recharge, as more/less meltwater was able to infiltrate in higher/lower areas. By increasing additionally the precipitation by 15%, the soil frost diminished slightly over the whole catchment. By combining both climate change scenarios, we may expect an increase in extreme events, as, on the one hand, the rainfall intensity increases, and, on the other hand, rain on snow events over frozen soils occurs more often in lower areas. In practice, this work shows the importance of better investigating the hydrothermal behaviour of alpine regions. Such a knowledge is necessary, as more and more efforts are put into managing efficiently, durably and globally the available water resources. This work stresses also the necessity to consider seasonally soil frost in alpine risk management. As an example, flooding is mostly a consequence of strong rain precipitation at high altitudes combined with heavy snowmelt. Obviously, the risk of extreme runoff events increases during frozen winters, when the soil infiltration capacity is further reduced by the soil ice. Also, it has been shown that unstable slopes are mostly related to specific hydrogeological situations, like strong precipitation, which induces a sharp increase in the underneath water circulation. The melt water in spring is hence a potential activating factor, and a frozen soil may reduce the risk of sliding, as less water infiltrates into the ground.

EPFL2003

Méthodologie de dimensionnement des zones de protection des captages d'eaux souterraines contre les polluants chimiques persistants

Thierry Bussard

This research proposes a general methodology allowing the delimitation of protection areas for abstracted groundwater against persistent chemical contaminants for the setting up of: (1) remediation programmes in the event of contamination and (2) prevention programmes, in a general way. Since such substances are mainly transported by water circulation, this approach suggests delineating protection areas on the basis of the complete groundwater flow cycle, from the surface of the catchment zone to the groundwater source itself. Areas with the highest contribution rate to the groundwater source will be protected first and foremost. The method under consideration is essentially applied to diffuse contaminants, such as pesticides or nitrates released by agriculture. If pollution is local, a standard method must be applied to treat the problem at the root. The methodology proposes the following steps, which start from the groundwater source and are widened, upstream, to the catchment zone: Identifying the aquifer portion that supplies the groundwater source. Defining, on the ground surface, the catchment zone of the groundwater source. Quantifying the recharge and discharge processes. Calculating the contribution to the groundwater abstraction rate of any point i on the catchment zone surface (Ci) by the following equation: Ci = Ii(1-ei)Pi [m/s] Ii : Infiltration of the precipitation or stream losses at point i [m/s]. ei : Discharge coefficient of water before reaching the main groundwater table (agricultural draining, perched water table, etc.), 0 ≤ e ≤ 1 [-]. Pi : Probability of a particle of water that reaches the groundwater table from point i at the surface going to the groundwater source, 0 ≤ P ≤ 1 [-]. Checking the results (water and mass balances). When the results are not satisfactory, the steps will have to be reiterated. Delineating protection areas (areas with the highest C will be primarily protected). With this approach, we propose not to confine ourselves taking the totality of the catchment zone as protection area against persistent contaminants (protection defined in most of the countries), but to define a smaller area of protection by selecting only the most contributive surfaces. As the acreage of the protection area can be considerably reduced, it will be possible to apply more severe regulations to it, which could never be done on the scale of the entire acreage of the catchment zone. Protection areas defined on this basis moreover allow target remediation solutions(1) which optimize the efficiency/cost ratio. They are, by their very concept, independent of the flux of contaminants at any given time and provide a tool for sustainable development and land planning. For each groundwater source, a rapid calculation based on the contribution field can be made to estimate the potential efficiency of the method and determine the remediation surface that is necessary to reduce contamination. In the same way, the effects of the potential development of the region can be evaluated. The contribution isoline that delimits the protection area can be proposed on the basis of this result. Three actual cases have been treated in order to test the method's applicability. The results are convincing in various porous or fractured aquifers. In the three sites, the results show that, with a similar remediation surface, remediation is more efficient when acting according to the concept of the methodology than when operating without spatial differentiation. ---------- (1) This study uses the concept of a "natural" remediation surface whereby contaminant leaching is reduced by a change in cultivation or in proceedings. The conversion of cultivated areas into meadows is, e.g., one of the most effective methods to reduce nitrates leaching.

EPFL2005