Your search keyword '"Kristine Uhlman"' showing total 18 results

1. 'Leaky Weirs' capture alluvial deposition and enhance seasonal mountain-front recharge in dryland streams

Author

Laura M. Norman, Kristine Uhlman, Hanna A. Coy, Natalie R. Wilson, Andrew M. Bennett, Floyd Gray, and Kurt T. Ehrenberg

Subjects

Alluvial fan, Ephemeral streams, Surface water–groundwater interactions, Restoration, Mountain-front recharge, Mountain-block recharge, Water supply for domestic and industrial purposes, TD201-500

Abstract

Abstract “Leaky weirs” are rock structures installed in dryland streams, which are anchored into exposed bedrock, loosely cemented, and designed to allow water to slowly pass through. They are being tested at a ranch in southeastern Arizona, USA, to restore and conserve the historic range and desert wetlands. Data are collected to assess how leaky weirs impact surface water, subsurface water, and groundwater recharge—including stream discharge, timing, and depth of infiltration, and groundwater elevations. Three adjacent watersheds, two with outlets just below leaky weirs and one with leaky weirs farther upstream, were instrumented with water-level loggers, wildlife cameras, and crest stage instruments with temperature sensors in the soil. As most groundwater recharge is assumed to be focused along the mountain fronts in this region, mountain-block recharge is also evaluated to differentiate between the two using isotope analyses. Finally, a single, late-season flood event is scrutinized to consider the leaky weir effect on all monitored components in the water budget. Results indicated groundwater flow is primarily from the mountains to the east via older, regional mountain-block recharge. However, the development of shallow alluvial aquifers is supported by the leaky weirs, that slow flows, capture permeable sediments, and allow infiltration, thus enhancing mountain-front recharge. In turn, these new pockets of water help support the restoration of historic wetlands. Sediment accumulates where leaky weirs are installed, reducing flashy peak flows, and resulting in a series of infiltration ponds along the channel that support vegetation during growing seasons and recharge the shallow aquifer during non-growing seasons.

Published

2025

2. Coal ash resources and potential for rare earth element production in the United States

Author

Robert C. Reedy, Bridget R. Scanlon, Davin A. Bagdonas, James C. Hower, Dennis James, J. Richard Kyle, and Kristine Uhlman

Subjects

Coal combustion byproducts, Coal ash, Fly ash, Bottom ash, Rare earth elements, Resource evaluation, Mining engineering. Metallurgy, TN1-997

Abstract

Abstract The renewable energy industry is heavily reliant on rare earth elements, underscoring the need to develop resources and production. The objective of this work was to estimate coal ash resources and potential for extraction of rare earth elements using data for the US. Data on spatiotemporal variability in coal ash resources and disposition were compiled from various federal databases and rare earth elements levels in ash were compiled from the literature. Results show that ~ 52 gigatons (Gt) of coal were produced in the US (1950–2021). Power plants account for most of the coal use, particularly since 1980. Coal ash (5.3 Gt) represents a mean of 10% of coal by weight, ranging from 6% for subbituminous to 14% for lignite. About 70% of coal ash is potentially accessible for rare earth element extraction (1985–2021) and was disposed in landfills and ponds with the remaining coal ash used onsite or sold. Median values of total rare earth elements are much higher in ashes derived from the Appalachian Basin (median 431 mg/kg) than in the Illinois (282 mg/kg) or Powder River basins (264 mg/kg). Considering the market value of rare earth oxides, potentially accessible ash volumes, and percent rare earth element extraction (30% Appalachian and Illinois Basins; 70% Powder River Basin) results in an estimated $8.4 billion value. This study provides fundamental information on accessible coal ash resources in the US, linkages to coal sources, and preliminary estimates of rare earth element levels for future development within the US.

Published

2024

3. Groundwater Withdrawals Associated with Oil and Gas Production from Water Supply Aquifers in Texas: Implications for Water Management Practices

Author

Katie Coeckelenbergh, Dorina Murgulet, Kristine Uhlman, and Chris Vickers

Subjects

low total dissolved solids, shallow oil and gas production, water supply aquifers, Texas, Water supply for domestic and industrial purposes, TD201-500

Abstract

The demand for water is continuing to increase as population and industry grow. The Natural Resources Defense Council indicated that Texas is at “extreme risk” for implementation of sustainable water management practices especially since groundwater is the supplier of much of the state’s freshwater. This study is designed to assess groundwater conservation practices in association with oil and gas production from the surrounding areas of the Carrizo-Wilcox formation in Texas. The results of this study reveal that the Railroad Commission of Texas (RRC), the governing agency for Texas oil and gas development, permits produced water to be discharged into surface waters if the discharged water quality meets Texas Surface Water Quality Standards (TSWQS) set by the Texas Commission on Environmental Quality (TCEQ) for the specific receiving water body. After careful evaluation of data provided by the Railroad Commission of Texas, it is believed that nearly 5,331,975 m3 (4,321 ac⋅ft) of produced water per year, with an average TDS of 960 mg L-1, is being removed from the Carrizo-Wilcox aquifer through discharge permits designated as “agricultural”. The RRC is not legally required to share the discharge information with local Groundwater Conservation Districts. Based on an evaluation of the reported Whole Effluent Toxicity (WET) test data, 69 discharges amount to total suspended solid (TDS) levels of less than 1,000 mg L-1, 35 are between 1,000-1,500 mg L-1, and 20 between 1,500 - 4,000 mg L-1. Although 69% of discharges exceed the secondary drinking water standard for TDS (500 mg L-1), the average of all discharges, 960 mg L-1, is in line with the arbitrary upper limit for freshwater based on the suitability for human consumption. In addition, the water quality of surface discharges complies with requirements for several water reuses associated with agricultural and industrial practices. The lack of communication between groundwater users leads to conflicting groundwater practices that have negative impacts such as contribution to aquifer over-exploitation and alteration of hydraulic gradients, in turn negatively impacting existing groundwater conservation efforts.

Published

2021

4. Enhancing drought resilience with conjunctive use and managed aquifer recharge in California and Arizona

Author

Bridget R Scanlon, Robert C Reedy, Claudia C Faunt, Donald Pool, and Kristine Uhlman

Subjects

managed aquifer recharge, conjunctive use, drought, groundwater storage, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Projected longer-term droughts and intense floods underscore the need to store more water to manage climate extremes. Here we show how depleted aquifers have been used to store water by substituting surface water use for groundwater pumpage (conjunctive use, CU) or recharging groundwater with surface water (managed aquifer recharge, MAR). Unique multi-decadal monitoring from thousands of wells and regional modeling datasets for the California Central Valley and central Arizona were used to assess CU and MAR. In addition to natural reservoir capacity related to deep water tables, historical groundwater depletion further expanded aquifer storage by ∼44 km ^3 in the Central Valley and by ∼100 km ^3 in Arizona, similar to or exceeding current surface reservoir capacity by up to three times. Local river water and imported surface water, transported through 100s of km of canals, is substituted for groundwater (≤15 km ^3 yr ^−1 , CU) or is used to recharge groundwater (MAR, ≤1.5 km ^3 yr ^−1 ) during wet years shifting to mostly groundwater pumpage during droughts. In the Central Valley, CU and MAR locally reversed historically declining water-level trends, which contrasts with simulated net regional groundwater depletion. In Arizona, CU and MAR also reversed historically declining groundwater level trends in active management areas. These rising trends contrast with current declining trends in irrigated areas that lack access to surface water to support CU or MAR. Use of depleted aquifers as reservoirs could expand with winter flood irrigation or capturing flood discharges to the Pacific (0–1.6 km ^3 yr ^−1 , 2000–2014) with additional infrastructure in California. Because flexibility and expanded portfolio options translate to resilience, CU and MAR enhance drought resilience through multi-year storage, complementing shorter term surface reservoir storage, and facilitating water markets.

Published

2016

5. Corrigendum: Enhancing drought resilience with conjunctive use and managed aquifer recharge in California and Arizona (2016 Environ. Res. Lett. 11 035013)

Author

Bridget R Scanlon, Robert C Reedy, Claudia C Faunt, Donald Pool, and Kristine Uhlman

Subjects

Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Published

2016

6. Assessing the Vulnerability of an Aquifer to Climate Variability through Community Participation in Arivaca, Arizona

Author

Anne Purkey‐Deller, Zack Guido, Michael A. Crimmins, Kristine Uhlman, Susanna Eden, and Chris Eastoe

Subjects

geography, geography.geographical_feature_category, Community participation, Vulnerability, Environmental science, Aquifer, Groundwater recharge, Water resource management, Groundwater

Published

2020

7. Controls on Methane Occurrences in Aquifers Overlying the Eagle Ford Shale Play, South Texas

Author

Jean-Philippe Nicot, Toti E. Larson, Patrick J. Mickler, Roxana Darvari, Ruth A. Costley, and Kristine Uhlman

Subjects

0208 environmental biotechnology, Geochemistry, Aquifer, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Methane, chemistry.chemical_compound, Organic matter, Computers in Earth Sciences, 0105 earth and related environmental sciences, Water Science and Technology, chemistry.chemical_classification, Hydrology, geography, geography.geographical_feature_category, business.industry, Fossil fuel, 020801 environmental engineering, Water resources, chemistry, business, Oil shale, Geology, Groundwater, Water well

Abstract

Assessing natural vs. anthropogenic sources of methane in drinking water aquifers is a critical issue in areas of shale oil and gas production. The objective of this study was to determine controls on methane occurrences in aquifers in the Eagle Ford Shale play footprint. A total of 110 water wells were tested for dissolved light alkanes, isotopes of methane, and major ions, mostly in the eastern section of the play. Multiple aquifers were sampled with approximately 47 samples from the Carrizo-Wilcox Aquifer (250-1200 m depth range) and Queen City-Sparta Aquifer (150-900 m depth range) and 63 samples from other shallow aquifers but mostly from the Catahoula Formation (depth 1 mg/L, 10 samples >10 mg/L). No dissolved methane samples exhibit thermogenic characteristics that would link them unequivocally to oil and gas sourced from the Eagle Ford Shale. In particular, the well water samples contain very little or no ethane and propane (C1/C2+C3 molar ratio >453), unlike what would be expected in an oil province, but they also display relatively heavier δ13 Cmethane (>-55‰) and δDmethane (>-180‰). Samples from the deeper Carrizo and Queen City aquifers are consistent with microbial methane sourced from syndepositional organic matter mixed with thermogenic methane input, most likely originating from deeper oil reservoirs and migrating through fault zones. Active oxidation of methane pushes δ13 Cmethane and δDmethane toward heavier values, whereas the thermogenic gas component is enriched with methane owing to a long migration path resulting in a higher C1/C2+C3 ratio than in the local reservoirs.

Published

2017

8. Methane Occurrences in Aquifers Overlying the Barnett Shale Play with a Focus on Parker County, Texas

Author

Patrick J. Mickler, Roxana Darvari, M. Clara Castro, Kristine Uhlman, Jean-Philippe Nicot, Ruth A. Costley, and Toti E. Larson

Subjects

Hydrology, geography, geography.geographical_feature_category, Paleozoic, business.industry, 0208 environmental biotechnology, Fossil fuel, Geochemistry, Aquifer, 02 engineering and technology, Methane, 020801 environmental engineering, chemistry.chemical_compound, Hydraulic fracturing, chemistry, Isotopes of carbon, Computers in Earth Sciences, business, Oil shale, Geology, Water Science and Technology, Water well

Abstract

Clusters of elevated methane concentrations in aquifers overlying the Barnett Shale play have been the focus of recent national attention as they relate to impacts of hydraulic fracturing. The objective of this study was to assess the spatial extent of high dissolved methane previously observed on the western edge of the play (Parker County) and to evaluate its most likely source. A total of 509 well water samples from 12 counties (14,500 km2 ) were analyzed for methane, major ions, and carbon isotopes. Most samples were collected from the regional Trinity Aquifer and show only low levels of dissolved methane (85% of 457 unique locations 20 mg/L) are limited to a few spatial clusters. The Parker County cluster area includes historical vertical oil and gas wells producing from relatively shallow formations and recent horizontal wells producing from the Barnett Shale (depth of ∼1500 m). Lack of correlation with distance to Barnett Shale horizontal wells, with distance to conventional wells, and with well density suggests a natural origin of the dissolved methane. Known commercial very shallow gas accumulations (

Published

2017

9. Controls on Methane Occurrences in Shallow Aquifers Overlying the Haynesville Shale Gas Field, East Texas

Author

Toti E. Larson, Ruth A. Costley, Jean-Philippe Nicot, Jordan Aldridge, Roxana Darvari, Michael Slotten, Kristine Uhlman, and Patrick J. Mickler

Subjects

0208 environmental biotechnology, Geochemistry, Aquifer, 02 engineering and technology, Natural Gas, Methane, chemistry.chemical_compound, Hydraulic fracturing, Natural gas, Oil and Gas Fields, Computers in Earth Sciences, Groundwater, Water Science and Technology, geography, geography.geographical_feature_category, Petroleum engineering, business.industry, Texas, 020801 environmental engineering, chemistry, Sedimentary rock, business, Oil shale, Water Pollutants, Chemical, Geology, Environmental Monitoring, Water well

Abstract

Understanding the source of dissolved methane in drinking-water aquifers is critical for assessing potential contributions from hydraulic fracturing in shale plays. Shallow groundwater in the Texas portion of the Haynesville Shale area (13,000 km2 ) was sampled (70 samples) for methane and other dissolved light alkanes. Most samples were derived from the fresh water bearing Wilcox formations and show little methane except in a localized cluster of 12 water wells (17% of total) in a approximately 30 × 30 km2 area in Southern Panola County with dissolved methane concentrations less than 10 mg/L. This zone of elevated methane is spatially associated with the termination of an active fault system affecting the entire sedimentary section, including the Haynesville Shale at a depth more than 3.5 km, and with shallow lignite seams of Lower Wilcox age at a depth of 100 to 230 m. The lignite spatial extension overlaps with the cluster. Gas wetness and methane isotope compositions suggest a mixed microbial and thermogenic origin with contribution from lignite beds and from deep thermogenic reservoirs that produce condensate in most of the cluster area. The pathway for methane from the lignite and deeper reservoirs is then provided by the fault system.

Published

2017

10. Contaminant transport mechanisms in karst terrains and implications on remediation

Author

Kristine Uhlman and Wendell Barner

Subjects

geography, geography.geographical_feature_category, Environmental remediation, Earth science, Environmental science, Terrain, Karst

Published

2018

11. Trace Element Behavior in Methane-Rich and Methane-Free Groundwater in North and East Texas

Author

Bridget R. Scanlon, Kristine Uhlman, Roxana Darvari, Patrick J. Mickler, and Jean-Philippe Nicot

Subjects

0208 environmental biotechnology, Mineralogy, Aquifer, 02 engineering and technology, 010501 environmental sciences, engineering.material, 01 natural sciences, Methane, chemistry.chemical_compound, Hydraulic fracturing, Natural gas, Computers in Earth Sciences, Groundwater, 0105 earth and related environmental sciences, Water Science and Technology, geography, geography.geographical_feature_category, business.industry, Trace element, Texas, 020801 environmental engineering, Trace Elements, chemistry, Environmental chemistry, engineering, Pyrite, business, Oil shale, Geology, Environmental Monitoring

Abstract

There is concern about adverse impacts of natural gas (primarily methane) production on groundwater quality; however, data on trace element concentrations are limited. The objective of this study was to compare the distribution of trace elements in groundwater samples with and without dissolved methane in aquifers overlying the Barnett Shale (Hood and Parker counties, 207 samples) and the Haynesville Shale (Panola County, 42 samples). Both shales have been subjected to intensive hydraulic fracturing for gas production. Well clusters with high dissolved methane were previously found in these counties and are thought to be of natural origin. Overall, groundwater in these counties is of excellent quality with typically low elemental concentrations. Several statistical analyses strongly suggest that most trace element concentrations, generally at low background levels, are no higher and even reduced when dissolved methane is present. In addition, trace element concentrations are not correlated with distance to gas wells. The reduction in trace element concentrations is attributed to anaerobic microbial degradation of methane, is associated with a higher pH (>8.5), and, likely, with precipitation of carbonates and pyrite and formation of clays. Trace and other elements are likely incorporated within the precipitating mineral crystalline network or sorbed. High pH values are found throughout these high-methane clusters (e.g., Parker-Hood cluster), even in subregions where methane is not present, which is consistent with a pervasive natural origin of dissolved methane rather than a limited gas well source.

Published

2017

12. Islamic Shari'a Contracts: Pre-Nuptial and Custody Protections

Author

Kristine Uhlman and Elisa Kisselburg

Subjects

education.field_of_study, Health (social science), Sociology and Political Science, Population, Foundation (evidence), Child custody, Islam, Criminology, Law, Islamic countries, Political science, Life-span and Life-course Studies, Sociocultural evolution, education

Abstract

The addition of a Shari'a-compliant parenting plan to American child custody orders can reduce the risk of abduction to Islamic countries where there are obstacles to securing a child's return. Determinations of custody in disputed divorce actions between parents seeking relief in American, secular courts can be complicated when those parents are dual nationals or citizens of other cultures and legal traditions. In Islam, marriage is formed by contract, responsibilities are defined by culture, and terms of divorce are set forth in the original marriage contract. A growing population of Muslim households in the United States needs legal practitioners, judges, mediators, and custody evaluators who understand the legal, sociocultural, and religious aspects that are the foundation of the Muslim family.

Published

2013

13. Methane Occurrences in Aquifers Overlying the Barnett Shale Play with a Focus on Parker County, Texas

Author

Jean-Philippe, Nicot, Patrick, Mickler, Toti, Larson, M, Clara Castro, Roxana, Darvari, Kristine, Uhlman, and Ruth, Costley

Subjects

Water Wells, Oil and Gas Fields, Natural Gas, Groundwater, Methane, Texas

Abstract

Clusters of elevated methane concentrations in aquifers overlying the Barnett Shale play have been the focus of recent national attention as they relate to impacts of hydraulic fracturing. The objective of this study was to assess the spatial extent of high dissolved methane previously observed on the western edge of the play (Parker County) and to evaluate its most likely source. A total of 509 well water samples from 12 counties (14,500 km

Published

2016

14. Controls on Methane Occurrences in Aquifers Overlying the Eagle Ford Shale Play, South Texas

Author

Jean-Philippe, Nicot, Toti, Larson, Roxana, Darvari, Patrick, Mickler, Kristine, Uhlman, and Ruth, Costley

Subjects

Groundwater, Methane, Texas, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Assessing natural vs. anthropogenic sources of methane in drinking water aquifers is a critical issue in areas of shale oil and gas production. The objective of this study was to determine controls on methane occurrences in aquifers in the Eagle Ford Shale play footprint. A total of 110 water wells were tested for dissolved light alkanes, isotopes of methane, and major ions, mostly in the eastern section of the play. Multiple aquifers were sampled with approximately 47 samples from the Carrizo-Wilcox Aquifer (250-1200 m depth range) and Queen City-Sparta Aquifer (150-900 m depth range) and 63 samples from other shallow aquifers but mostly from the Catahoula Formation (depth150 m). Besides three shallow wells with unambiguously microbial methane, only deeper wells show significant dissolved methane (22 samples1 mg/L, 10 samples10 mg/L). No dissolved methane samples exhibit thermogenic characteristics that would link them unequivocally to oil and gas sourced from the Eagle Ford Shale. In particular, the well water samples contain very little or no ethane and propane (C1/C2+C3 molar ratio453), unlike what would be expected in an oil province, but they also display relatively heavier δ

Published

2016

15. Recharge in Desert Regions Around the World

Author

Kristine Uhlman

Subjects

Hydrology, Infiltration (hydrology), geography, geography.geographical_feature_category, Snowmelt, Depression-focused recharge, Aquifer, Groundwater recharge, Surface runoff, Surface water, Arid, Geology

Abstract

Following Potter's classification, arid and semiarid regions are those whose precipitation to evaporation (P/E) ratios are smaller than 0.5 and between 0.5 and 1.0, respectively. In addition to a lower net precipitation rate, rainfalls are typically infrequent and of short duration; high-intensity seasonal storms contribute a major portion of the annual rainfall over short periods of time. Under these conditions, the shallow soil surface layer infiltration capacity may be exceeded and excess overland flow propagates rapidly to flash flooding. Even low-intensity rainfalls, can lead to significant surface runoff when desert soil crusts have formed. Water focused and concentrated by topography into ephemeral washes, wadis, sabkhas, and playas provides locations of enhanced recharge in arid areas. A significant component of recharge to arid basin aquifers occurs along mountain fronts. Important aspects along the mountain front include the partitioning of rainfall and snowmelt into surface runoff, deep infiltration along fractures and faults, and vegetation-controlled evapotranspiration. Focused flow along mountain stream channels into the major washes in the Tucson Basin (Arizona) visibly infiltrates flood-plain sediment, and surface water commonly does not leave the watershed. Half the annual recharge of 9 to 10 mm/year to the Ogallala Aquifer in the southern High Plains (Oklahoma and Texas) occurs through playa floors that cover only 6% of the aquifer land surface area. Keywords: arid hydrology; recharge; desert hydrology; vadose transport; ephemeral flow; semiarid; isotope tracers; aquifer sustainability; precipitation to evaporation (P/E) ratios; washes; wadis; sabkhas; playas; infiltration; macropore; chloride mass balance; groundwater

Published

2004

16. Public supply well vulnerability

Author

Kristine, Uhlman

Subjects

Water Supply, Water Wells, Water Pollution, Chemical, Humans, Risk Assessment, Environmental Monitoring

Published

2014

17. Focus Issue on Public Supply Well Vulnerability

Author

Kristine Uhlman

Subjects

Public supply, Focus (computing), business.industry, Vulnerability assessment, Environmental monitoring, Vulnerability, Environmental science, Water supply, Computers in Earth Sciences, Risk assessment, business, Environmental planning, Water Science and Technology

Published

2014

18. The Geochemistry of Boron in a Landfill Monitoring Program

Author

Kristine Uhlman

Subjects

Hydrology, geography, Municipal solid waste, geography.geographical_feature_category, Peat, Piezometer, Environmental engineering, Geochemistry, Landfill liner, Monitoring program, Environmental science, Leachate, Groundwater, Water Science and Technology, Civil and Structural Engineering, Water well

Abstract

Ground water monitoring data collected during the past eight years at a permitted municipal solid waste (MSW) disposal facility located in the midwestern United States indicated fluctuations in typical leachate indicator parameter concentrations. Apparent trends in the data inferred leachate outbreak, generating suspicion as to the integrity of the landfill liner. Eight ground water monitoring wells were installed in three distinct geologic units at the landfill facility, including glacial drift, silurian dolomite, and a post-glacial peat fen, which is downgradient from the landfill. Piezometer nests were used to define ground water gradients at the site. Using boron as an indicator, the occurrence of analytes of concern in the downgradient monitoring wells were shown to be indicative of the natural geochemistry of site ground water. This work emphasizes the importance of understanding site hydrogeology during the interpretation of ground water quality data.

Published

1991