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Modeling Hydrodynamics Water Temperature And Water Quality In The Klamath River Upstream Of Keno Dam Oregon 200609
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Book Synopsis Modeling Hydrodynamics, Water Temperature, and Water Quality in the Klamath River Upstream of Keno Dam, Oregon, 2006?09 by : Annett B. Sullivan
Download or read book Modeling Hydrodynamics, Water Temperature, and Water Quality in the Klamath River Upstream of Keno Dam, Oregon, 2006?09 written by Annett B. Sullivan and published by CreateSpace. This book was released on 2014-07-10 with total page 78 pages. Available in PDF, EPUB and Kindle. Book excerpt: A hydrodynamic, water temperature, and water-quality model was constructed for a 20-mile reach of the Klamath River downstream of Upper Klamath Lake, from Link River to Keno Dam, for calendar years 2006–09. The two-dimensional, laterally averaged model CE-QUAL-W2 was used to simulate water velocity, ice cover, water temperature, specific conductance, dissolved and suspended solids, dissolved oxygen, total nitrogen, ammonia, nitrate, total phosphorus, orthophosphate, dissolved and particulate organic matter, and three algal groups. The Link–Keno model successfully simulated the most important spatial and temporal patterns in the measured data for this 4-year time period. The model calibration process provided critical insights into water-quality processes and the nature of those inputs and processes that drive water quality in this reach. The model was used not only to reproduce and better understand water-quality conditions that occurred in 2006–09, but also to test several load- reduction scenarios that have implications for future water- resources management in the river basin.
Book Synopsis Modeling Hydrodynamics, Water Temperature, and Water Quality in the Klamath River Upstream of Keno Dam, Oregon, 2006-09 by :
Download or read book Modeling Hydrodynamics, Water Temperature, and Water Quality in the Klamath River Upstream of Keno Dam, Oregon, 2006-09 written by and published by . This book was released on 2011 with total page 70 pages. Available in PDF, EPUB and Kindle. Book excerpt: "A hydrodynamic, water temperature, and water-quality model was constructed for a 20-mile reach of the Klamath River downstream of Upper Klamath Lake, from Link River to Keno Dam, for calendar years 2006-09. The two-dimensional, laterally averaged model CE-QUAL-W2 was used to simulate water velocity, ice cover, water temperature, specific conductance, dissolved and suspended solids, dissolved oxygen, total nitrogen, ammonia, nitrate, total phosphorus, orthophosphate, dissolved and particulate organic matter, and three algal groups. The Link-Keno model successfully simulated the most important spatial and temporal patterns in the measured data for this 4-year time period. The model calibration process provided critical insights into water-quality processes and the nature of those inputs and processes that drive water quality in this reach. The model was used not only to reproduce and better understand water-quality conditions that occurred in 2006-09, but also to test several load-reduction scenarios that have implications for future water-resources management in the river basin. The model construction and calibration process provided results concerning water quality and transport in the Link-Keno reach of the Klamath River, ranging from interesting circulation patterns in the Lake Ewauna area to the nature and importance of organic matter and algae. These insights and results include: Modeled segment-average water velocities ranged from near 0.0 to 3.0 ft/s in 2006 through 2009. Travel time through the model reach was about 4 days at 2,000 ft3/s and 12 days at 700 ft3/s flow. Flow direction was aligned with the upstream-downstream channel axis for most of the Link-Keno reach, except for Lake Ewauna. Wind effects were pronounced at Lake Ewauna during low-flow conditions, often with circulation in the form of a gyre that rotated in a clockwise direction when winds were towards the southeast and in a counterclockwise direction when winds were towards the northwest. Water temperatures ranged from near freezing in winter to near 30 °C at some locations and periods in summer; seasonal water temperature patterns were similar at the inflow and outflow. Although vertical temperature stratification was not present at most times and locations, weak stratification could persist for periods up to 1-2 weeks, especially in the downstream parts of the reach. Thermal stratification was important in controlling vertical variations in water quality. The specific conductance, and thus density, of tributaries within the reach usually was higher than that of the river itself, so that inflows tended to sink below the river surface. This was especially notable for inflows from the Klamath Straits Drain, which tended to sink to the bottom of the Klamath River at its confluence and not mix vertically for several miles downstream. The model was able to capture most of the seasonal changes in the algal population by modeling that population with three algal groups: blue-green algae, diatoms, and other algae. The blooms of blue-green algae, consisting mostly of Aphanizomenon flos aquae that entered from Upper Klamath Lake, were dominant, dwarfing the populations of the other two algae groups in summer. A large part of the blue-green algae population that entered this reach from upstream tended to settle out, die, and decompose, especially in the upper part of the Link-Keno reach. Diatoms reached a maximum in spring and other algae in midsummer. Organic matter, occurring in both dissolved and particulate forms, was critical to the water quality of this reach of the Klamath River, and was strongly tied to nutrient and dissolved-oxygen dynamics. Dissolved and particulate organic matter were subdivided into labile (quickly decaying) and refractory (slowing decaying) groups for modeling purposes. The particulate matter in summer, consisting largely of dead blue-green algae, decayed quickly. Consequently, this particulate matter exerted a high oxygen demand over short periods and contributed strongly to low dissolved-oxygen conditions present during summer and fall. Particulate matter in winter and dissolved organic matter throughout the year was largely refractory (slow to decay). The slower decay rate of this refractory material translates to less oxygen demand over short periods, but also will manifest itself as higher oxygen demand downstream of Keno Dam. The decay and settling of algae and particulate organic matter in the upper part of the Link-Keno reach of the Klamath River has important implications for nutrients. Decay releases nitrogen and phosphorus from particulate forms into dissolved forms such as ammonia, which had elevated concentrations in the downstream part of this reach in summer. Dissolved nutrients showed consistent seasonal patterns that were simulated well by the model. Ammonia concentrations were highest in midsummer and winter and lowest in spring. Nitrate concentrations were highest in winter and lowest in summer. Orthophosphorus concentrations were at their maximum in midsummer and lowest in winter. Comparing modeled hourly nutrient loads at the Link River inflow and the Keno Dam outflow, the Link-Keno reach and its tributaries were a source of total nitrogen and total phosphorus to downstream reaches in early spring and a sink in summer. Dissolved-oxygen concentrations were near saturation in winter, but periods of supersaturation could occur in spring and early summer as oxygen was produced by algal photosynthesis. In mid- to late summer, oxygen sources were overwhelmed by oxygen sinks, especially the decay of organic matter in the water column and river bottom. Extensive anoxia occurred during this period. The sediment oxygen demand was dynamic and represented a relatively fast decomposition of materials deposited during that same year. The labile material was eventually exhausted and reaeration from the atmosphere allowed the system to slowly return towards oxygen saturation in fall. The model simulated the general temporal and spatial patterns in dissolved oxygen, although the inclusion of macrophytes and additional information on reaeration processes, organic matter, and algal dynamics could improve the simulation of dissolved oxygen. Calendar years 2007 and 2008 had more extensive datasets than 2006 and 2009. The models built with less extensive input data were still able to reproduce the patterns in the measured data reasonably well. These findings underline the importance of using results from the 2007 and 2008 detailed field data and experimental work to determine robust model rates, stoichiometry relations, and other parameters that can be applied successfully to years with less data and with different conditions. The 2006-09 models were applied to examine the effects of several reduced-loading scenarios consistent with total maximum daily load (TMDL) targets. The water quality of the Link River inflow was modified in one scenario so that it met the in-lake phosphorus targets of the Upper Klamath Lake TMDL. Point and nonpoint sources along the Klamath River were set to be in compliance with their Klamath River TMDL allocations in another scenario. Results from those scenarios indicated that dissolved-oxygen conditions improved the most when Link River loads were reduced; depending on year, average June through October dissolved-oxygen concentrations increased between 1.9 and 3.2 mg/L. Similarly, ammonia concentrations improved the most under this scenario, with an average June through October concentration decrease between 0.20 and 0.34 mg/L. Orthophosphorus concentrations were decreased significantly in both scenarios that reduced concentrations from Link River and scenarios that reduced concentrations from in-reach point and nonpoint sources, with June through October concentration decreases between 0.02 and 0.06 mg/L. The calibrated models are useful tools that reproduce the most important water-quality processes occurring in the Link-Keno reach of the Klamath River. These models are accurate enough to provide insights into the nature of those processes and the probable effects of proposed management and water-quality improvement strategies."--Executive summary.
Book Synopsis Modeling hydrodynamics, water temperature, and suspended sediment in Detroit Lake, Oregon by :
Download or read book Modeling hydrodynamics, water temperature, and suspended sediment in Detroit Lake, Oregon written by and published by DIANE Publishing. This book was released on with total page 108 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon, 2000-03 by : Annett Brigitte Sullivan
Download or read book Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon, 2000-03 written by Annett Brigitte Sullivan and published by . This book was released on 2005 with total page 48 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Water Quality Modeling in the Systems Impact Assessment Model for the Klamath River Basin - Keno, Oregon to Seiad Valley, California by : R. Blair Hanna
Download or read book Water Quality Modeling in the Systems Impact Assessment Model for the Klamath River Basin - Keno, Oregon to Seiad Valley, California written by R. Blair Hanna and published by . This book was released on 2000 with total page 164 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Download or read book HEC-5Q written by R. G. Willey and published by . This book was released on 1986 with total page 26 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon, 2000-03 by : Annett Brigitte Sullivan
Download or read book Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon, 2000-03 written by Annett Brigitte Sullivan and published by . This book was released on 2005 with total page 38 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Simulating Water Temperature of the Klamath River Under Dam Removal and Climate Change Scenerios by : U.S. Department Of The Interior
Download or read book Simulating Water Temperature of the Klamath River Under Dam Removal and Climate Change Scenerios written by U.S. Department Of The Interior and published by CreateSpace. This book was released on 2014-03 with total page 84 pages. Available in PDF, EPUB and Kindle. Book excerpt: A one-dimensional daily averaged water temperature model was used to simulate Klamath River temperatures for two management alternatives under historical climate conditions and six future climate scenarios.
Book Synopsis River and Reservoir Systems Water Quality Modeling Capability by : R. G. Willey
Download or read book River and Reservoir Systems Water Quality Modeling Capability written by R. G. Willey and published by . This book was released on 1982 with total page 18 pages. Available in PDF, EPUB and Kindle. Book excerpt: The capability exists within the Corps to evaluate the water quality impacts of alternative proposals for river and/or reservoir projects. The capability and example applications of the various water quality models available from the Hydrologic Engineering Center are described. (Author).
Book Synopsis Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon ..., U.S. Geological Survey, Scientific Investigations Report 2004-5261, 2005 by :
Download or read book Modeling Hydrodynamics, Temperature, and Water Quality in Henry Hagg Lake, Oregon ..., U.S. Geological Survey, Scientific Investigations Report 2004-5261, 2005 written by and published by . This book was released on 2005* with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Water Quality Modeling Study by : Alaska Energy Authority
Download or read book Water Quality Modeling Study written by Alaska Energy Authority and published by . This book was released on 2012 with total page 12 pages. Available in PDF, EPUB and Kindle. Book excerpt: The goal of the water quality studies is to assess the effects of the proposed Project on water quality in the Susitna River basin and to identify and develop protection, mitigation, and enhancement measures that can be implemented to minimize these effects.
Book Synopsis Temperature Prediction in Stratified Water by : Patrick J. Ryan
Download or read book Temperature Prediction in Stratified Water written by Patrick J. Ryan and published by . This book was released on 1971 with total page 144 pages. Available in PDF, EPUB and Kindle. Book excerpt: Predictions of the complex annual cycle of temperature changes in a lake or reservoir are necessary if proper water quality control is to be achieved. Many lakes and reservoirs exhibit horizontal homogeneity and thus a time-dependent, one-dimensional model describing the temperature variation in the vertical direction is adequate. A discretized mathematical model was developed based on the absorption and transmission of solar radiation, convection due to surface cooling and advection due to inflows and outflows. The model contains provision for simultaneous or intermittent withdrawal from multi-level outlets and time of travel for inflows within the reservoir.
Book Synopsis Modeling the Hydrodynamics and Water Quality of the Lower Minnesota River Using CE-QUAL-W2 by : David L. Smith
Download or read book Modeling the Hydrodynamics and Water Quality of the Lower Minnesota River Using CE-QUAL-W2 written by David L. Smith and published by . This book was released on 2012 with total page 194 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Application of a Hydrodynamic and Water Quality Model for Inland Surface Water Systems by : Lubo Liu
Download or read book Application of a Hydrodynamic and Water Quality Model for Inland Surface Water Systems written by Lubo Liu and published by . This book was released on 2018 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: This chapter introduces basic concepts, properties, and principles of different processes in inland surface water and analytical methodologies. The fundamentals of surface water hydrodynamics, including water properties, hydrodynamic processes, Cartesian coordinate-based governing equations, and boundary and initial conditions were reviewed. The fate and transport of contaminants in surface water were introduced. Based on aforementioned theory and principles, two hydrodynamic-water quality models were developed for studying a lake and a river, respectively. A stratified 3D model was used to investigate the circulation and E. coli transport in the nearshore region of Lake Michigan. The modeling results show that stratified phenomenon exists in the near region, and a 3D model is necessary even though a previous 2D model works well for the shallow water environment. A 2D depth-averaged water quality model was developed to estimate the fate and transport of four contaminants in the San Joaquin River of California. The modeling results indicate that it took 20 days for these contaminants to transport from the upstream to the downstream in the research domain. These models can be effectively used for inland surface water restoration and management.
Book Synopsis Development of a CE-QUAL-W2 Temperature Model for Crystal Springs Lake, Portland, Oregon by : Norman Loris Buccola
Download or read book Development of a CE-QUAL-W2 Temperature Model for Crystal Springs Lake, Portland, Oregon written by Norman Loris Buccola and published by . This book was released on 2016 with total page 26 pages. Available in PDF, EPUB and Kindle. Book excerpt: During summer 2014, lake level, streamflow, and water temperature in and around Crystal Springs Lake in Portland, Oregon, were measured by the U.S. Geological Survey and the City of Portland Bureau of Environmental Services to better understand the effect of the lake on Crystal Springs Creek and Johnson Creek downstream. Johnson Creek is listed as an impaired water body for temperature by the Oregon Department of Environmental Quality (ODEQ), as required by section 303(d) of the Clean Water Act. A temperature total maximum daily load applies to all streams in the Johnson Creek watershed, including Crystal Springs Creek. Summer water temperatures downstream of Crystal Springs Lake and the Golf Pond regularly exceed the ODEQ numeric criterion of 64.4 °F (18.0 °C) for salmonid rearing and migration. To better understand temperature contributions of this system, the U.S. Geological Survey developed two-dimensional hydrodynamic water temperature models of Crystal Springs Lake and the Golf Pond. Model grids were developed to closely resemble the bathymetry of the lake and pond using data from a 2014 survey. The calibrated models simulated surface water elevations to within 0.06 foot (0.02 meter) and outflow water temperature to within 1.08 °F (0.60 °C). Streamflow, water temperature, and lake elevation data collected during summer 2014 supplied the boundary and reference conditions for the model. Measured discrepancies between outflow and inflow from the lake, assumed to be mostly from unknown and diffuse springs under the lake, accounted for about 46 percent of the total inflow to the lake. Model simulations (scenarios) were run with lower water surface elevations in Crystal Springs Lake and increased shading to the lake to assess the relative effect the lake and pond characteristics have on water temperature. The Golf Pond was unaltered in all scenarios. The models estimated that lower lake elevations would result in cooler water downstream of the Golf Pond and shorter residence times in the lake. Increased shading to the lake would also provide substantial cooling. Most management scenarios resulted in a decrease in 7-day average of daily maximum values by about 2.0-4.7 °F (1.1 -2.6 °C) for outflow from Crystal Springs Lake during the period of interest. Outflows from the Golf Pond showed a net temperature reduction of 0.5-2.7 °F (0.3-1.5 °C) compared to measured values in 2014 because of solar heating and downstream warming in the Golf Pond resulting from mixing with inflow from Reed Lake.
Book Synopsis Water Temperature Modeling in Streams to Support Ecological Restoration by : Nathaniel L Butler
Download or read book Water Temperature Modeling in Streams to Support Ecological Restoration written by Nathaniel L Butler and published by . This book was released on 2015 with total page 162 pages. Available in PDF, EPUB and Kindle. Book excerpt: Water temperature is a critical water quality parameter that affects salmonid survival by influencing its metabolism and growth at all life stages. Stream temperature is an especially important parameter in California rivers where it frequently limits the range of salmonids. Anthropogenic activities have increased stream temperature and degraded spawning, holding, and rearing habitats, and this has contributed to declines in salmonid populations in California. Fisheries managers have a range of analytical and empirical tools available to assess and quantify elevated stream temperature conditions, but many of these tools do not focus on water temperature conditions at the spatial and temporal scales important to salmonids. My research focuses on assessing water temperature at the watershed and upwelling hyporheic scale which are critical to salmonid survival as stream temperature approaches thermal tolerances. I developed a model to calculate water temperature at locations throughout a watershed to provide a method to evaluate the availability and connectivity of suitable thermal habitat throughout a stream network. The model used a linear weighted average of the maximum and minimum air temperatures of the current and 4 prior days. The weighting parameter is dependent upon upstream drainage area enabling the application of the model to both small tributaries and large mainstem streams. I used historical data from the Sonoma Creek, Napa River, and Russian River watersheds to develop, test, calibrate, and partially validate the model. Model results from Sonoma Creek and Napa River indicated it was generally able to estimate daily average water temperature within 1.5 degrees C of the observed water temperature. Data from the Russian River highlighted the model was limited to streams without significant hydrologic modifications or geologic constraints that forced groundwater to the surface. A 1-D advection dispersion heat transport model was developed to quantify the upwelling hyporheic temperature that provides cold water thermal refugia along a streambed for salmonids. I analyzed hyporheic temperature measured at five sites in a previous research program across sixteen kilometers of Deer Creek near Vina, California, to test, calibrate, and partially validate the model. At three sites, I found the 1-D advection and dispersion were the dominant heat transport mechanisms with model root mean square error less than 0.6 degrees C. At two sites, the model was not applicable because modeling results indicated that surface flow rate variations, solar radiation, and multi-day flow paths also influenced the upwelling hyporheic temperature. Modeling was valuable for highlighting the contribution of these additional processes from that of 1-D advection dispersion. The availability of monitoring data over the summer-fall period was essential for modeling upwelling temperature dynamics along a semi-natural channel.
Book Synopsis Principles of Surface Water Quality Modeling and Control by : Robert V. Thomann
Download or read book Principles of Surface Water Quality Modeling and Control written by Robert V. Thomann and published by HarperCollins Publishers. This book was released on 1987 with total page 664 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book teaches the fundamentals and principles which underlie the mathematical modeling techniques used to analyze the quality of surface waters. The text first provides an overview of the different bodies of water in which water quality problems need to be addressed before examining specific problems that occur across all bodies of water.
