NU Water-Related Research in the Upper Elkhorn NRD

The list below shows water-related research being conducted within your NRD or that affects your NRD. They are sorted by water topic, then by primary contact's last name.

Displaying 16 records found for Upper Elkhorn NRD


Topic Climate
Project's Primary Contact Information
Name Shulski, Martha
Unit High Plains Regional Climate Center
Email mshulski3@unl.edu
Phone 402-472-6711
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=474
Project Information
Title High Plains Regional Climate Center - Monitoring Stations
Description

As the demand for water grows, it is important to have reliable information for various assessments, such as drought, fire, and water development. In an effort to understand the surface hydrology and the water and energy interactions at the surface, scientists with the High Plains Regional Climate Center have installed a series of monitoring stations that collect temperature, humidity, solar radiation, windspeed and direction, soil temperature, precipitation and soil moisture data. These stations take hourly and daily data which can be used to calculate evapotranspiration and water balance terms. Monitoring equipment is located near Higgins Ranch, Sparks, Merritt, Ainsworth, New Port, Barta, Gudmundsens, Halsey, and Merna.

Volunteers supplement these stations by using rain gauges to monitor precipitation; volunteers enter their data online as part of the Nebraska Rainfall Assessment and Information Network (NeRAIN). In total volunteers from 40 states contribute precipitation data to the Community Collaborative Rain, Hail and Snow Network (CoCoRaHS). The CoCoRaHS network has been incorporated into the Applied Climate Information System (ACIS), which allows resource managers, researchers, and decision-makers to better access data.

Project Support National Climatic Data Center
Project Website http://hprcc.unl.edu
Report
Current Status Continuing
Topic Crop Nutrient Use
Project's Primary Contact Information
Name Wortmann, Charles
Unit Agronomy and Horticulture
Email cwortmann2@unl.edu
Phone 402-472-2909
Web Page http://agronomy.unl.edu/wortmann
Project Information
Title Nitrogen Use Efficiency of Irrigated Corn for Three Cropping Systems in Nebraska
Other(s) Charles Shapiro, Agronomy & Horticulture, cshapiro@unl.edu; Richard Ferguson, Agronomy & Horticulture, rferguson1@unl.edu; Gary Hergert, Panhandle Research & Extension Center, ghergert1@unl.edu 
Description

Overview Nitrogen fertilizer will continue to be indispensible for meeting global food, feed, and fiber needs. Voroneyand Derry (2008) estimated that 340 million Mg yr-1 N is fixed by natural means, including lightning and biological N fixation, and 105 million Mg yr-1 is fixed by human activities, including burning of fossil fuels and N fertilizer production, with N fixation by human activities expected to continue to increase. Townsend and Howarth (2010) estimated the amount of N fixed by human activities to be about 180 million Mg yr-1, with most used as mineral fertilizer. Fertilizer N production has important environmental implications with an average of ~2.55 kg CO2 emitted per kg fertilizer N fixed and transported (Liska et al., 2009). Th e amount of N applied is associated with emission of N2O (IPCC–OECD, 1997) and N accumulation in sensitive aquatic, marine, and terrestrial ecosystems (Groffman, 2008; Malakoff , 1998). Th e challenge is to produce more grain to meet growing global needs with high NUE.

Conclusions Across diverse production environments, high corn yields can be achieved with efficient use of soil and applied N and without high risk of NO3 -N leaching to groundwater. With excellent farm management, recovery of applied fertilizer-N in high-yielding corn fields of Nebraska was well above 60 to 70% at the economically optimal nitrogen rate (EONR), resulting in low residual soil nitrate nitrogen (RSN) levels. Agronomic efficiency and crop partial factor productivity (PFP), the Nitrogen use efficiency (NUE) components most closely related to profitability of production, can also be high at EONR. Less preplant and more in-season N application may be especially important for drybean (CD) which had low recovery efficiency (RE) and much postharvest RSN compared with corn (CC) and soybean (CS). The levels of NUE achieved in our study for CC and CS far exceed current national or regional means, demonstrating the potential for high NUE with high yield corn production. Further NUE efficiency may be gained through more accurate in-season N application such as with use of the presidedress NO3 test (Andraski and Bundy, 2002) and spatial variation in N rate in response to variation in crop need, such as through use of reflectance sensors (Scharf and Lory, 2009; Barker and Sawyer, 2010; Roberts et al., 2010).

Project Support Nebraska State Legislature, Nebraska Agricultural Business Association
Project Website
Report Wortmann_NUE.pdf
Current Status Completed
Topic Extension
Project's Primary Contact Information
Name Kranz, Bill
Unit Northeast Research and Extension Center
Email wkranz1@unl.edu
Phone 402-475-3857
Web Page
Project Information
Title Northeast Research and Extension Center - Haskell Agricultural Laboratory
Other(s) Charles Shapiro, Northeast Research and Extension Center, cshapiro1@unl.edu; Dave Shelton, Northeast Research and Extension Center, dshelton2@unl.edu; Sue Lackey, Conservation and Survey, slackey1@unl.edu; Terry Mader, Haskell Ag. Lab, tmader1@unl.edu 
Description

The role of the faculty and staff in this unit is to prevent or solve problems using research based information. Faculty and staff subscribe to the notion that their programs should be high quality, ecologically sound, economically viable, socially responsible and scientifically appropriate. Learning experiences can be customized to meet the needs of a wide range of business, commodity, or governmental organizations based upon the many subject matter disciplines represented. As part of the University of Nebraska, the Northeast Center faculty and staff consider themselves to be the front door to the University in northeast Nebraska. Through well targeted training backgrounds and continuous updating via the internet and other telecommunications technologies, faculty and staff have the most current information available to help their clientele.

The Haskell Ag. Lab is a University of Nebraska research farm located 1.5 miles east of the Dixon County Fairgrounds in Concord. This 320 acre farm was donated to the University of Nebraska by the C.D. Haskell family of Laurel in 1956. A number of demonstrations and projects are going on at the Haskell Ag. Lab, including a riparian buffer strip demonstration and a study to evaluate the effect of irrigation on soybean aphid population dynamics. Other studies focus on:

Subsurface Drip Irrigation: In the spring of 2007 a new subsurface drip irrigation system was installed on a 4 acre portion of the farm with sandy loam soils. The initial objective of the research is to collect field data to document crop water use rates for new corn varieties. Specifically, the work will concentrate on varieties that have different drought resistance ratings to improve the accuracy of the information provided to producers via the High Plains Regional Climate Center. In 2007, two varieties were planted and five irrigation treatments were imposed ranging from dryland to full irrigation. The data will also be used to develop improved local crop production functions for use in the Water Optimizer spreadsheet.

Hormones in Livestock Waste: This project will evaluate the fate of both naturally occurring and synthetic hormones that are associated with solid waste harvested from beef cattle feeding facilities. The research involves: 1) tracking the fate of hormonal compounds from the feedlot into surface run-off that would make its way into a liquid storage lagoon; 2) establishing stockpiled and composted sources of the solid manure removed from the feedlot; and 3) applying stockpiled and composted manure to cropland areas under different tillage systems and native grasses. Once the manure is applied the runoff potential will be evaluated using a rainfall simulator. Research will then focus on whether plants that could be a source of food for wildlife and/or domestic animals take up the hormones. (More information about this project is available; see projects listed under Dan Snow.)

Project Support Varies according to program and project - for more information see http://nerec.unl.edu/ Hormone Project funded by the U.S. Environmental Protection Agency
Project Website http://nerec.unl.edu/
Report
Current Status Continuous
Topic Extension
Project's Primary Contact Information
Name Kranz, Bill
Unit Northeast Research and Extension Center
Email wkranz1@unl.edu
Phone 402-584-3857
Web Page http://bse.unl.edu/web/bse/wkranz1
Project Information
Title Demonstration Projects and Field Tours
Other(s) Charles Shapiro, Northeast Research and Extension Center, cshapiro1@unl.edu. 
Description

A project associated with using beef manure compost on sandy soils is being conducted near Pierce and Plainview as a means of improving soil quality, using a beef production by-product in crop production and reducing commercial fertilizer application. The data collected at these two sites has been presented by Charles Shapiro at several educational meetings across northeast Nebraska. The project shows a slight improvement is some parameters, but the cost of transportation reduces the quantity of compost that can be transported and so the effect on soil physical properties is minimal, although soil phosphorus levels are increasing.

Near Pierce a project funded by the Lower Elkhorn Natural Resources District aims to demonstrate the impact of reducing season long water application by 10% on corn yield. At this site the farmer uses a computer control panel to speed up or slow down his center pivot automatically to apply 10% less or 10% more than his normal application, respectively. Nitrogen is being applied at three different rates to demonstrate the adequacy of the UNL Calculation Procedure.

Near Brunswick a project funded by the Upper Elkhorn Natural Resources District aims to develop improved nitrogen credit following soybeans in a corn-soybean rotation. Six nitrogen treatments and 6 different cropping sequences have been imposed to determine the nitrogen credit from soybeans on sandy soils. This project will run through the 2008 growing season. To date data suggests lower nitrogen credits on the sands than the silt loam soils in eastern Nebraska.

Project Support Lower Elkhorn Natural Resources District, Upper Elkhorn Natural Resources District
Project Website
Report
Current Status Continuous
Topic Hydrology
Project's Primary Contact Information
Name Chen, Xun-Hong
Unit School of Natural Resources
Email xchen2@unl.edu
Phone 402-472-0772
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=19
Project Information
Title Hydrologic Connections in the Elkhorn River Basin
Other(s) Sue Lackey, Conservation and Survey, slackey1@unl.edu 
Description This project involves investigating the hydrologic connections between streams and the adjacent aquifer systems in the Elkhorn River Basin. Researchers have used a Geoprobe direct-push technique, in-situ permeameter tests, and a thermal camera to collect data in this basin. Research has been conducted in Taylor Creek (west of the City of Madison), in Maple Creek, and two sites in the Elkhorn River near Norfolk and Meadow Grove. Ultimately this data will be used for integrated management of surface and groundwater resources.
Project Support Nebraska Department of Natural Resources, Upper Elkhorn Natural Resources District, Lower Elkhorn Natural Resources District
Project Website
Report
Current Status Continuous
Pic 1 Project Image
Pic Caption 1 This image shows our work in the Elkhorn River near Meadow Grove and in Taylor Creek. 
Pic 2 Project Image 2
Pic Caption 2 Direct-push techniques used by UNL researchers for study of stream-aquifer connections in Madison County, Nebraska. 
Topic Hydrology
Project's Primary Contact Information
Name Lenters, John
Unit School of Natural Resources
Email jlenters2@unl.edu
Phone 402-472-9044
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=743
Project Information
Title On Basin Residence Time and Annual Hydrology: Development of Annual Hydrology Model of the Sandhills Rivers
Other(s) Erkan Istanbulluoglu, University of Washington, erkani@u.washington.edu; Durelle Scott, Virginia Tech, dscott@vt.edu; Tiejun Wang, University of Washington-Seattle, tjwang@u.washington.edu 
Description

Simple models of annual and mean annual basin runoff and evapotranspration, such as the one proposed by Budyko, are useful for investigating the relationship between river flow and climate, and planning water storage structures in basins where long term streamflow measurements are not available. Such models are often based on the assumption that annual precipitation is in balance with annual runoff and evapotranspiration, and change in water storage of the basin is negligible. In basins where groundwater is the dominant source of streamflow this assumption hardly holds.

In this study first we develop a technique to investigate groundwater residence time to identify time scales over which a simple model of mean annual runoff can be meaningfully used. The model is applied in the Niobrara and Loup Rivers. Second we develop an annual hydrology model by solving the rate of change in basin storage. The runoff component of the model is based on the well-known linear reservoir model and a parameterization to characterize runoff on saturated areas. River water storages and streamflow diverted for irrigation are included as inputs in the model. The model explained as high as 80% of the annual variability of runoff in the Niobrara River at the Sparks gage. The model underscores the importance of saturation overland flow in the basin. Finally we used the model to investigate climate change scenarios, including extreme dry and wet conditions, as well as scenarios for the Medieval Warm Period during which Sandhills were destabilized as suggested by geological evidence.

Project presentation at the 2008 Water Colloquium

Project Support National Science Foundation
Project Website
Report Lenters_Groundwater.pdf
Current Status Published "On the role of groundwater and soil texture in the regional water balance: An investigation of the Nebraska Sand Hills", USA, Water Resour. Res., 45, W10413, doi:10.1029/2009WR007733.
Topic Hydrology
Project's Primary Contact Information
Name Pederson, Darryll
Unit Earth and Atmospheric Sciences
Email dpederson2@unl.edu
Phone 402-472-7563
Web Page http://eas.unl.edu/people/faculty_page.php?lastname=Pederson&firstname=Darryll&type=REG
Project Information
Title Waterfalls on the Niobrara River's Spring-fed Tributaries
Description The waterfalls on the spring-fed tributaries of the Niobrara River downstream from Valentine, Nebraska are unique in that the waterfalls are convex downstream. Groundwater discharge on either side of the waterfalls has led to significant weathering because of freeze/thaw cycles in the winter and wet/dry cycles in the summer. The water falling over the face of the falls protects them from the two weathering processes. Because the weathering rates on either side are higher than the erosion rates from falling water, the face of the falls is convex downstream. Similar waterfall face morphology occurs on the Island of Kauai where the main weathering processes are driven by vegetation and the presence of water.
Project Support National Park Service through the Great Plains Cooperative Ecosystem Studies Unit
Project Website http://snr.unl.edu/gpcesu/Project_library.htm
Report Waterfalls_Abstract.pdf
Current Status Completed
Topic Hydrology
Project's Primary Contact Information
Name Wang, Tiejun
Unit School of Natural Resources
Email tiejunwang215@yahoo.com
Phone
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=945
Project Information
Title Niobrara River Flow Variability
Other(s) Erkan Istanbulluoglu, University of Washington, erkani@u.washington.edu 
Description This project develops a database for hydrological and climatological variables within the Niobrara River basin so that researchers may study flow variability in the Niobrara River and its historical changes. Analysis includes all existing and discontinued streamflow gages within the system. Surface water diversion data are also collected to relate to changes in the flow discharge. Annual water yield of the river is studied at Sparks and Verdel gages. A lumped annual water yield model is developed to identify the natural variables that control runoff. The model uses annual runoff as forcing variable, as well as water diversions as outflux from the system. The model is currently being extended to monthly time scales.
Project Support Nebraska Game and Parks Commission, National Park Service
Project Website
Report
Current Status Underway
Topic Sandhills Studies and Modeling
Project's Primary Contact Information
Name Billesbach, Dave
Unit Biological Systems Engineering
Email dbillesbach1@unl.edu
Phone 402-472-7961
Web Page http://bse.unl.edu/faculty/Billesbach.shtml
Project Information
Title Effects of Precipitation and Groundwater on Grassland Productivity in the Nebraska Sand Hills
Other(s) Tim Arkebauer, Agronomy and Horticulture, tarkebauer1@unl.edu 
Description

In the Sand Hills the depth to groundwater greatly affects the types and amounts of grasses that grow there, suggesting a strong linkage between groundwater, precipitation, and grass productivity. Wet meadows are where the water rable is usually less than a meter below the surface and make up about 10% of the Sand Hills land area. Dry valleys are where the water table never intersects the land surface and usually lies several meters below; dry valleys also make up about 10% of the Sand Hills land area. Except for lakes and wetlands (about 2% of the land area), the rest of the Sand Hills is dunal uplands where the water table is many meters below the surface.

It has long been assumed that the Sand Hills are a recharge zone for the underlying aquifer and that local precipitation more than accounts for the water usage of surface vegetation. This research measures how much water enters the Sand Hills ecosystem (via precipitation) and how much water leaves the land surface - the Sand Hills surface water balance. Research shows that Sand Hills surface water is lost primarily through evapotranspiration, or surface water evaporation and plant transpiration, with the relative size of each varying greatly depending on the time of year and other factors, such as drought. Research also shows that: 1) the most water is transferred to the atmosphere from wet meadows, followed by dry valleys and dunal uplands; 2) the close proximity to the aquifer acts as a buffer to both wet meadows and dry valleys, but not to dunal uplands; and 3) groundwater buffering is most affected by regional rather than local precipitation events. The long-term goal of this project is to study and better understand the relationship between water and the vegetative land cover (carbon).

Project Support n/a
Project Website
Report Billesbach_SandHills_Water.pdf
Current Status Continuing
Topic Sandhills Studies and Modeling
Project's Primary Contact Information
Name Efting, Aris
Unit School of Natural Resources
Email aefting@unl.edu
Phone 402-472-3471
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=226
Project Information
Title Determining Toxic Algal Bloom Frequency in Nebraska Lakes
Description Research has been conducted in the Sandhills to determine whether or not there has been an increase in toxic algal blooms. Four different lakes were cored to identify the lakes' history of toxic algal blooms and determine whether there is an increase in toxin concentrations post 1950.
Project Support Layman Fund
Project Website
Report
Current Status Underway
Topic Sandhills Studies and Modeling
Project's Primary Contact Information
Name Wedin, Dave
Unit School of Natural Resources
Email dwedin1@unl.edu
Phone 402-472-9608
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=128
Project Information
Title Sand Hills Biocomplexity Project
Other(s) Vitaly Zlotnik, Department of Geosciences, vzlotnik1@unl.edu. 
Description

The Sand Hills, the largest sand dune area in the Western Hemisphere, is now stabalized by native grasses. This was not always the case. The Sand Hills have mobilized several times over the last 10,550 years. Major droughts destabilized significant portions of the Sand Hills as recently as 1000 years ago. The stability of the Sand Hills affects not only hundreds of cattle ranches, but also the recharge of the High Plains Aquifer. Of the total groundwater stored in this vast aquifer, 65% occurs in Nebraska and over half of that lies under the Sand Hills. The groundwater connection is obvious throughout the region. Due to the high water table, interdunal valleys in portions of the Sand Hills contain extensive complexes of lakes, wetlands, and naturally sub-irrigated wet meadows, which together cover over 10% of the landscape.

The Sand Hills Biocomplexity Project is a major federal project led by Professor Wedin. The project is aimed at testing whether:

  1. Evapotranspiration (ET) from wet valleys buffers the impacts of short-term drought on upland grasslands through local climate feedbacks. (resistance stability)
  2. When wetlands go dry, the combined effect of lost upland grass cover and lost wetland ET creates a desertification feedback that amplifies drought impacts.
  3. Since subregions of the Sand Hills differ in their extent of interdunal wetlands, subregions respond differently to paleo and historic droughts, thus enabling landowners to prepare for future droughts.
  4. Increased groundwater recharge when dunes are bare hastens the rise of groundwater levels, which, together with the rapid recovery of warm season grasses, restabilizes the dunes. (resilience stability)

The project's Grassland Destabilization Experiment (GDEX) is studying what happens to a Sand Hills dune when the vegetation dies. Researchers have created 10 circular plots at the Barta Brothers Ranch, each 120 meters in diameter, and used herbicide to kill all the vegetation on several of them. The plots are kept clear of vegetation, so that information on vegetation coverage, root mass, soil organic matter, and sand movement may be monitored and recorded to determine the stability of the plots. Results indicate that the Sand Hills may be more stable than previously thought; that is, ersosion is just starting to occur were vegetation was killed two years ago. Additional studies are needed to determine what happens when sand dunes become mobile.

As a part of this project, Professor Vitaly Zlotnik carries out research on groundwater recharge, hydraulic properties of the dune cover, and the climate change effects on groundwater recharge.

Project Support National Science Foundation
Project Website http://sandhills-biocomplexity.unl.edu/
Report
Current Status n/a
Topic Water Quality
Project's Primary Contact Information
Name Kolok, Alan
Unit Biology, UNO
Email akolok@mail.unomaha.edu
Phone 402-554-3545
Web Page http://www.unomaha.edu/envirotox/whoiam.php
Project Information
Title The Watershed as A Conceptual Framework for the Study of Environmental and Human Health
Other(s) Cheryl L. Beseler, Department of Environmental, Agricultural and Occupational Health, UNMC, cbeseler@unmc.edu; Xun-Hong Chen, School of Natural Resources, xchen2@unl.edu; Patrick J. Shea, School of Natural Resources, pshea1@unl.edu 
Description

The watershed provides a physical basis for establishing linkages between aquatic contaminants, environmental health and human health. Current attempts to establish such linkages are limited by environmental and epidemiological constraints. Environmental limitations include difficulties in characterizing the temporal and spatial dynamics of agricultural runoff, in fully understanding the degradation and metabolism of these compounds in the environment, and in understanding complex mixtures. Epidemiological limitations include difficulties associated with the organization of risk factor data and uncertainty about which measurable endpoints are most appropriate for an agricultural setting. Nevertheless, the adoption of the watershed concept can alleviate some of these difficulties. From an environmental perspective, the watershed concept helps identify differences in land use and application of agrichemicals at a level of resolution relevant to human health outcomes. From an epidemiological perspective, the watershed concept places data into a construct with environmental relevance. This project uses the Elkhorn River watershed as a case study to show how the watershed can provide a conceptual framework for studies in environmental and human health.

Environmental sampling is necessary for evaluating exposure to hormone disrupting chemicals (HDCs); however, sampling is not systematic in time or space, nor does it represent the time frame necessary to adequately link it to human disease outcomes. Although data from municipal sources are available and reliable, countless private drinking water wells go untested and unmonitored. These wells may be in areas vulnerable to concentrated reservoirs of contaminants due to the soil type, infiltration rate, runoff potential, organic matter and erodibility coupled with land use in the region and the chemical properties of the contaminants introduced into the environment. The lack of a defined boundary and introduction of exposure heterogeneity is one of the primary reasons why associations to health outcomes cannot be shown in environmental epidemiological studies.

The use of the watershed provides a natural boundary and the potential within this boundary to obtain denominator data. Based on the characteristics of the watershed combined with sampling data, shared exposures can be identified and intermediate hypotheses tested using sentinel markers of exposure in fish and humans. Lastly, comparable groups identified in other watersheds with similar characteristics but different surrounding land uses can be used to replicate findings.

Project Support Department of Environmental, Agricultural and Occupational Health, University of Nebraska Medical Center
Project Website
Report Kolok_Watershed.pdf
Current Status Published in Environmental Health Insights 2009 3:1-10
Topic Water Quality
Project's Primary Contact Information
Name Kolok, Alan
Unit Biology, UNO
Email akolok@mail.unomaha.edu
Phone 402-554-3545
Web Page http://www.unomaha.edu/envirotox/whoiam.php
Project Information
Title Occurrence and biological effect of exogenous steroids in the Elkhorn River, Nebraska
Other(s) Daniel D. Snow, School of Natural Resources, dsnow1@unl.edu; Satomi Kohno, Department of Zoology, University of Florida, kohno@ufl.edu; Marlo K. Sellin, Department of Biology, UNO, msellin@mail.unomaha.edu; Louis J. Guillette Jr., Department of Zoology, University of Florida, ljg@ufl.edu 
Description

Recent studies of surface waters in North America, Japan and Europe have reported the presence of steroidogenic agents as contaminants. This study had three objectives:

  1. to determine if steroidogenic compounds are present in the Elkhorn River,
  2. to determine if sediments collected from the Elkhorn River can act as a source of steroidogenic compounds to aquatic organisms, and
  3. to determine if site-specific biological effects are apparent in the hepatic gene expression of fathead minnows.

Evidence was obtained using three approaches:

  1. deployment of polar organic chemical integrative samplers (POCIS),
  2. deployment of caged fathead minnows, and
  3. a laboratory experiment in which POCIS and fish were exposed to sediments from the deployment sites.

Deployment sites included: the Elkhorn River immediately downstream from a Nebraska wastewater treatment plant, two waterways (Fisher Creek and Sand Creek) likely to be impacted by runoff from cattle feeding operations, and a reference site unlikely to be impacted by waste water inputs. The POCIS extracts were analyzed for a number of natural steroids and metabolites, as well as four different synthetic steroids: ethinylestradiol, zearalonol, 17-trenbolone and melengestrol acetate. Estrogenic and androgenic metabolites, as well as progesterone and trace levels of melengestrol acetate were detected in POCIS deployed at each site. POCIS deployed in tanks containing field sediments from the four sites did not accumulate the synthetic steroids except for ethinylestradiol, which was detected in the aquarium containing sediments collected near the wastewater treatment plant. Fish deployed in Sand Creek and at the wastewater treatment plant experienced significantly elevated levels of gene expression for two genes (StAR and P450scc) relative to those deployed in Fisher Creek. Fish exposed to the sediments collected from Sand Creek had significantly higher levels of hepatic StAR and P450scc gene expression than did fish exposed to sediments from the two other field sites, as well as the no-sediment control tank.

In conclusion:

  1. detectable levels of steroidogenic compounds were detected in passive samplers deployed in the Elkhorn River,
  2. sediments do not appear to be a significant source for steroidogenic compounds, and
  3. site-specific differences were found in mRNA expression among the different treatment groups of fish; however, a functional explanation for these differences is not readily forthcoming.
Project Support Nebraska Game and Parks Commission, U.S. Geological Survey's Section 104b Program as administered by the UNL Water Center, US Environmental Protection Agency Greater Opportunities Fellowship, Dr. Daniel Villeneuve, US Environmental Protection Agency
Project Website
Report Kolok_Elkhorn.pdf
Current Status Published in Science of the Total Environment 2007 388:104-115
Topic Water Quality
Project's Primary Contact Information
Name Spalding, Roy
Unit Agronomy and Horticulture
Email rspalding1@unl.edu
Phone 402-472-8214
Web Page http://agronomy.unl.edu/spalding
Project Information
Title Risk-Managed Approach for Routing Petroleum Pipelines: Keystone XL Pipeline, Nebraska
Other(s) Aaron Hirsh, Department of Civil Engineering, ajhirsh@huskers.unl.edu 
Description

TransCanada’s proposed international crude oil pipeline route over sensitive, relatively pristine, subirrigated land underlain by the Ogallala aquifer led to increased scrutiny and eventual rejection of the Keystone XL pipeline. Pipeline routing could be made much more acceptable by adopting risk-managed routes that lessen the potential to adversely impact high-quality groundwater and, should a release occur, decrease the longevity of hazardous groundwater contaminants. Threats to water quality are taken quite seriously in states like Nebraska where 85% of the population depend on groundwater for potable water.

The authors proposed a southeasterly route through Holt, Antelope and Pierce counties, to the existing north-south Keystone 1 pipeline, avoiding the Ogallala aquifer beneath the fragile and pristine Sandhills, sub-irrigated meadows and areas with very shallow water tables. The risk-managed route through these three counties is through overlying row-cropped land underlain by already contaminated Ogallala groundwater to the Keystone 1 corridor.

Since little is known about the potential movement of dilbit (diluted bitumen) to groundwater at release sites, the study states that one of the best ways to minimize risks from a potential spill is to carefully select a pipeline route with minimal environmental risk and reasonable length. There are so many variables including the chemical composition of the dilbit, ambient temperature, depth to groundwater, emergency cleanup practices and other factors, that predicting the exact mechanism of contaminant movement to the aquifer is complicated. Additionally, the existing nitrate contamination in Holt, Antelope and Pierce counties stretches for over 100 miles and 1 million acres. These leached soils enhance the degradation of hazardous petroleum compounds in groundwater.

Project Support Nebraska Ethanol Board and Hatch grant 21-6222-1055
Project Website
Report Risk_Managed_Petroleum_Pipeline.pdf
Current Status Completed
Pic 1 Project Image
Topic Wildlife
Project's Primary Contact Information
Name Pegg, Mark
Unit School of Natural Resources
Email mpegg2@unl.edu
Phone 402-472-6824
Web Page http://snr.unl.edu/aboutus/who/people/faculty-member.asp?pid=739
Project Information
Title Habitat Usage of Missouri River Paddlefish Project
Description Sediment from the Niobrara River has created a delta area near the headwaters of Lewis and Clark Lake, the reservoir formed by Gavins Point Dam on the Missouri River. This sediment aggregation has reduced reservoir volume and threatens to fill the reservoir; therefore, restoration of reservoir capacity has been proposed by means of high-velocity water releases from upstream mainstem dams. Biologists, however, have reported that this delta area may serve as spawning grounds for native fishes like paddlefish, and may provide suitable spawning habitat for federally endangered pallid sturgeon. This situation has created a unique paradox where information is needed to provide insight into fulfilling both the river management needs and biological needs in the Missouri River. This project will use paddlefish telemetry to study spawning success.

Click here to read Brenda Pracheil's dissertation on Paddlefish populations

Project Support Nebraska Environmental Trust
Project Website
Report Pracheil et al_Fisheries_2012.pdf
Current Status Completed
Topic Wildlife
Project's Primary Contact Information
Name Young, Chelsey
Unit Biology, UNK
Email youngca2@unk.edu
Phone 507-469-8284
Web Page
Project Information
Title A range-wide assessment of plains topminnow (Fundulus sciadicus) distribution and potential threats
Other(s) W. Wyatt Hoback, Biology UNK, hobackww@unk.edu; Keith Koupal, Biology UNK; Justin Haas 
Description The plains topminnow, Fundulus sciadicus, was once distributed from the Mississippi River to the Rocky Mountains, north to South Dakota and as far south as Oklahoma. Two centers of distribution are recognized. One is centered in Nebraska and the second is centered in Missouri. The geographic range of plains topminnow has decreased in the past decades. Plains topminnow are now considered a species of special concern in the state of Nebraska and listed as a Tier 1 species in the Nebraska Natural Legacy Project. Elimination of plains topminnow populations has been associated with introduction of invasive species, as well as loss of backwater habitats due to drought and lowered water tables. The objective of this project is to provide an updated assessment of plains topminnow distribution and population status as compared to all available historical records. Between 2004 and the present, sampling of plains topminnow revealed that in Nebraska 77% of historic Nebraska sites no longer contain plains topminnow populations. The sampling of remaining historic sites in Nebraska and neighboring states will continue in the 2009 sampling season.
Project Support n/a
Project Website
Report topminnow_range_reduction.pdf
Current Status Completed