Limnological and Climatic Environments at Upper Klamath Lake, Oregon during the past 45 000 years

Upper Klamath Lake, in south-central Oregon, contains long sediment records with well-preserved diatoms and lithological variations that reflect climate-induced limnological changes. These sediment archives complement and extend high resolution terrestrial records along a north–south transect that includes areas influenced by the Aleutian Low and Subtropical High, which control both marine and continental climates in the western United States. The longest and oldest core collected in this study came from the southwest margin of the lake at Caledonia Marsh, and was dated by radiocarbon and tephrochronology to an age of about 45 ka. Paleolimnological interpretations of this core, based upon geochemical and diatom analyses, have been augmented by data from a short core collected from open water environments at nearby Howards Bay and from a 9-m core extending to 15 ka raised from the center of the northwestern part of Upper Klamath Lake. Pre- and full-glacial intervals of the Caledonia Marsh core are characterized and dominated by lithic detrital material. Planktic diatom taxa characteristic of cold-water habitats (Aulacoseira subarctica and A. islandica) alternate with warm-water planktic diatoms (A. ambigua) between 45 and 23 ka, documenting climate changes at millennial scales during oxygen isotope stage (OIS) 3. The full-glacial interval contains mostly cold-water planktic, benthic, and reworked Pliocene lacustrine diatoms (from the surrounding Yonna Formation) that document shallow water conditions in a cold, windy environment. After 15 ka, diatom productivity increased. Organic carbon and biogenic silica became significant sediment components and diatoms that live in the lake today, indicative of warm, eutrophic water, became prominent. Lake levels fell during the mid-Holocene and marsh environments extended over the core site. This interval is characterized by high levels of organic carbon from emergent aquatic vegetation (Scirpus) and by the Mazama ash (7.55 ka), generated by the eruption that created nearby Crater Lake. For a brief time the ash increased the salinity of Upper Klamath Lake. High concentrations of molybdenum, arsenic, and vanadium indicate that Caledonia Marsh was anoxic from about 7 to 5 ka. After the mid-Holocene, shallow, but open-water environments returned to the core site. The sediments became dominated (>80%) by biogenic silica. The open-water cores show analogous but less extreme limnological and climatic changes more typical of mid-lake environments. Millennial-scale lake and climate changes during OIS 3 at Upper Klamath Lake contrast with a similar record of variation at Owens Lake, about 750 km south. When Upper Klamath Lake experienced cold-climate episodes during OIS 3, Owens Lake had warm but wet episodes; the reverse occurred during warmer intervals at Upper Klamath Lake. Such climatic alternations apparently reflect the variable position and strength of the Aleutian Low during the mid-Wisconsin.     

A COMPUTERIZED TECHNIQUE FOR ESTIMATING THE HYDRAULIC CONDUCTIVITY OF AQUIFERS FROM SPECIFIC CAPACITY DATA

Abstract. Specific capacity data obtained from well construction reports can provide useful estimates of hydraulic conductivity (K). A simple computer program has been developed which can correct specific capacity data for partial penetration and well loss and, using an iterative technique, provide rapid estimates of K at hundreds of data points. The program allows easy data handling and is easily linked with existing statistical programs or contour mapping routines. The method was tested at two field sites in Wisconsin, one underlain by a sandy outwash aquifer, the other by fractured dolomite. In both areas, estimates of K from corrected specific capacity data agree reasonably well with data from pumping tests.     

A simple daily soil–water balance model for estimating the spatial and temporal distribution of groundwater recharge in temperate humid areas

Quantifying the spatial and temporal distribution of natural groundwater recharge is usually a prerequisite for effective groundwater modeling and management. As flow models become increasingly utilized for management decisions, there is an increased need for simple, practical methods to delineate recharge zones and quantify recharge rates. Existing models for estimating recharge distributions are data intensive, require extensive parameterization, and take a significant investment of time in order to establish. The Wisconsin Geological and Natural History Survey (WGNHS) has developed a simple daily soil–water balance (SWB) model that uses readily available soil, land cover, topographic, and climatic data in conjunction with a geographic information system (GIS) to estimate the temporal and spatial distribution of groundwater recharge at the watershed scale for temperate humid areas. To demonstrate the methodology and the applicability and performance of the model, two case studies are presented: one for the forested Trout Lake watershed of north central Wisconsin, USA and the other for the urban-agricultural Pheasant Branch Creek watershed of south central Wisconsin, USA. Overall, the SWB model performs well and presents modelers and planners with a practical tool for providing recharge estimates for modeling and water resource planning purposes in humid areas.

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Resumen La cuantificación de la distribución espacial y temporal de la recarga natural de agua subterránea es un requisito previo para una modelación y una gestión efectivas de las aguas subterráneas. Dado que se está incrementando el uso de los modelos de flujo para la toma de decisiones de gestión, existe una necesidad creciente de métodos simples y prácticos para delimitar las zonas de recarga y cuantificar los rangos de la misma. Los modelos existentes para la estimación de la distribución de la recarga requieren datos intensivos, una parametrización extensiva y una inversión de tiempo significativa para ser establecidos. El Servicio Geológico y de Historioa Natural de Wisconsin (WGNHS) ha desarrollado un modelo simple de balance diario de agua en el suelo (SWB) que usa de forma sencilla datos disponibles de suelo, de cobertera, topográficos y climáticos conjuntamente con un Sistema de Información Geográfica (GIS) para estimar la distribución espacial y temporal de la recarga de aguas subterráneas a escala de cuenca para zonas templadas húmedas. Para demostrar la metodología, aplicabilidad y el comportamiento del modelo, se presentan dos casos: uno en la cuenca boscosa de Trout Lake, en la zona Norte-Central de Wisconsin, USA y el otro en la Cuenca urbano-agrícola de Pheasant Branch Creek, Sur-Centro de Winconsin, USA. En conjunto, el modelo SWB funciona bien y presenta a los modeladores y planificadores una herramienta práctica para llevar a cabo una estimación de la recarga para propósitos de modelación y planificación de los recursos de agua en zonas húmedas.

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Résumé Quantifier les distributions temporelle et spatiale de la réalimentation naturelle des eaux souterraines est en règle générale un préalable à une modélisation et une gestion efficaces des eaux souterraines. Etant donné que les modèles numériques sont utilisés de manière croissante dans les prises de décisions en matière de gestion, il existe un besoin accru pour des méthodes simples et pratiques, afin de délimiter les zones d’alimentation et de quantifier les recharges associées. Les modèles existants, destinés à l’estimation de la répartition des réalimentations, demandent énormément de données, un paramétrage long, et un investissement conséquent en temps de mise en œuvre. Le Wisconsin Geologic and Natural History Survey (WGNHS) a développé un modèle simple basé sur un bilan en eau quotidien dans les sols (SWB); il utilise les données directement disponibles sur les sols, l’occupation des sols, la topographie et le climat, en conjonction avec un Système d’Information Géographique, afin d’estimer les distributions temporelle et spatiale de la réalimentation des eaux souterraines à l’échelle du bassin versant, pour les zones humides tempérées. Afin de démontrer la méthodologie, l’applicabilité et les performances du modèle, deux applications sont présentées: la première sur le bassin versant boisé de Trout Lake au centre-nord du Wisconsin (Etats-Unis), et le second sur le bassin versant agricole et urbanisé de Pheasant Branch Creek au centre-sud du Wisconsin. Le modèle SWB se comporte globalement bien, et offre aux modélisateurs un outil fonctionnel pour estimer les réalimentations, dans le cadre de modélisations et de plans de gestion des ressources en eau souterraine dans les zones humides.

     

Depletion Mapping and Constrained Optimization to Support Managing Groundwater Extraction

Groundwater models often serve as management tools to evaluate competing water uses including ecosystems, irrigated agriculture, industry, municipal supply, and others. Depletion potential mapping—showing the model‐calculated potential impacts that wells have on stream baseflow—can form the basis for multiple potential management approaches in an oversubscribed basin. Specific management approaches can include scenarios proposed by stakeholders, systematic changes in well pumping based on depletion potential, and formal constrained optimization, which can be used to quantify the tradeoff between water use and stream baseflow. Variables such as the maximum amount of reduction allowed in each well and various groupings of wells using, for example, K‐means clustering considering spatial proximity and depletion potential are considered. These approaches provide a potential starting point and guidance for resource managers and stakeholders to make decisions about groundwater management in a basin, spreading responsibility in different ways. We illustrate these approaches in the Little Plover River basin in central Wisconsin, United States—home to a rich agricultural tradition, with farmland and urban areas both in close proximity to a groundwater‐dependent trout stream. Groundwater withdrawals have reduced baseflow supplying the Little Plover River below a legally established minimum. The techniques in this work were developed in response to engaged stakeholders with various interests and goals for the basin. They sought to develop a collaborative management plan at a watershed scale that restores the flow rate in the river in a manner that incorporates principles of shared governance and results in effective and minimally disruptive changes in groundwater extraction practices.     

Characterization of fracture connectivity in a siliciclastic bedrock aquifer near a public supply well (Wisconsin, USA)

In order to protect public supply wells from a wide range of contaminants, it is imperative to understand physical flow and transport mechanisms in the aquifer system. Although flow through fractures has typically been associated with either crystalline or carbonate rocks, there is growing evidence that it can be an important component of flow in relatively permeable sandstone formations. The objective of this work is to determine the role that fractures serve in the transport of near-surface contaminants such as wastewater from leaking sewers, to public supply wells in a deep bedrock aquifer. A part of the Cambrian aquifer system in Madison, Wisconsin (USA), was studied using a combination of geophysical, geochemical, and hydraulic testing in a borehole adjacent to a public supply well. Data suggest that bedrock fractures are important transport pathways from the surface to the deep aquifer. These fractured intervals have transmissivity values several orders of magnitude higher than non-fractured intervals. With respect to rapid transport of contaminants, high transmissivity values of individual fractures make them the most likely preferential flow pathways. Results suggest that in a siliciclastic aquifer near a public supply well, fractures may have an important role in the transport of sewer-derived wastewater contaminants.