D. Kirk Nordstrom (Former Employee)
Science and Products
Filter Total Items: 164
Solute and geothermal flux monitoring using electrical conductivity in the Madison, Firehole, and Gibbon Rivers, Yellowstone National Park Solute and geothermal flux monitoring using electrical conductivity in the Madison, Firehole, and Gibbon Rivers, Yellowstone National Park
The thermal output from the Yellowstone magma chamber can be estimated from the Cl flux in the major rivers in Yellowstone National Park; and by utilizing continuous discharge and electrical conductivity measurements the Cl flux can be calculated. The relationship between electrical conductivity and concentrations of Cl and other geothermal solutes (Na, SO4, F, HCO3, SiO2, K, Li, B, and...
Authors
R. Blaine McCleskey, Laura Clor, Jacob B. Lowenstern, William C. Evans, D. Kirk Nordstrom, Henry Heasler, Mark Huebner
Models, validation, and applied geochemistry: Issues in science, communication, and philosophy Models, validation, and applied geochemistry: Issues in science, communication, and philosophy
Models have become so fashionable that many scientists and engineers cannot imagine working without them. The predominant use of computer codes to execute model calculations has blurred the distinction between code and model. The recent controversy regarding model validation has brought into question what we mean by a ‘model’ and by ‘validation.’ It has become apparent that the usual...
Authors
D. Kirk Nordstrom
Simultaneous oxidation of arsenic and antimony at low and circumneutral pH, with and without microbial catalysis Simultaneous oxidation of arsenic and antimony at low and circumneutral pH, with and without microbial catalysis
Arsenic and Sb are common mine-water pollutants and their toxicity and fate are strongly influenced by redox processes. In this study, simultaneous Fe(II), As(III) and Sb(III) oxidation experiments were conducted to obtain rates under laboratory conditions similar to those found in the field for mine waters of both low and circumneutral pH. Additional experiments were performed under...
Authors
Maria P. Asta, D. Kirk Nordstrom, R. Blaine McCleskey
A new method of calculating electrical conductivity with applications to natural waters A new method of calculating electrical conductivity with applications to natural waters
A new method is presented for calculating the electrical conductivity of natural waters that is accurate over a large range of effective ionic strength (0.0004–0.7 mol kg−1), temperature (0–95 °C), pH (1–10), and conductivity (30–70,000 μS cm−1). The method incorporates a reliable set of equations to calculate the ionic molal conductivities of cations and anions (H+, Li+, Na+, K+, Cs+...
Authors
R. Blaine McCleskey, D. Kirk Nordstrom, J. N. Ryan, J. W. Ball
Comparison of electrical conductivity calculation methods for natural waters Comparison of electrical conductivity calculation methods for natural waters
The capability of eleven methods to calculate the electrical conductivity of a wide range of natural waters from their chemical composition was investigated. A brief summary of each method is presented including equations to calculate the conductivities of individual ions, the ions incorporated, and the method's limitations. The ability of each method to reliably predict the conductivity...
Authors
R. Blaine McCleskey, D. Kirk Nordstrom, Joseph N. Ryan
Mine waters: Acidic to circumneutral Mine waters: Acidic to circumneutral
Acid mine waters, often containing toxic concentrations of Fe, Al, Cu, Zn, Cd, Pb, Ni, Co, and Cr, can be produced from the mining of coal and metallic deposits. Values of pH for acid mine waters can range from –3.5 to 5, but even circumneutral (pH ≈ 7) mine waters can have high concentrations of As, Sb, Mo, U, and F. When mine waters are discharged into streams, lakes, and the oceans...
Authors
D. Kirk Nordstrom
Sulfide mineral oxidation Sulfide mineral oxidation
No abstract available.
Authors
D. Kirk Nordstrom
Fluoride geochemistry of thermal waters in Yellowstone National Park: I. Aqueous fluoride speciation Fluoride geochemistry of thermal waters in Yellowstone National Park: I. Aqueous fluoride speciation
Thermal water samples from Yellowstone National Park (YNP) have a wide range of pH (1–10), temperature, and high concentrations of fluoride (up to 50 mg/l). High fluoride concentrations are found in waters with field pH higher than 6 (except those in Crater Hills) and temperatures higher than 50 °C based on data from more than 750 water samples covering most thermal areas in YNP from...
Authors
Y. Deng, D. Kirk Nordstrom, R. Blaine McCleskey
Ammonium in thermal waters of Yellowstone National Park: Processes affecting speciation and isotope fractionation Ammonium in thermal waters of Yellowstone National Park: Processes affecting speciation and isotope fractionation
Dissolved inorganic nitrogen, largely in reduced form (NH4(T)≈NH4(aq)++NH3(aq)o), has been documented in thermal waters throughout Yellowstone National Park, with concentrations ranging from a few micromolar along the Firehole River to millimolar concentrations at Washburn Hot Springs. Indirect evidence from rock nitrogen analyses and previous work on organic compounds associated with...
Authors
J.M. Holloway, D. Kirk Nordstrom, J.K. Böhlke, R. Blaine McCleskey, J.W. Ball
Quality of our groundwater resources: Arsenic and fluoride Quality of our groundwater resources: Arsenic and fluoride
Groundwater often contains arsenic or fluoride concentrations too high for drinking or cooking. These constituents, often naturally occurring, are not easy to remove. The right combination of natural or manmade conditions can lead to elevated arsenic or fluoride which includes continental source rocks, high alkalinity and pH, reducing conditions for arsenic, high phosphate, high...
Authors
D. Kirk Nordstrom
Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters
The formation of acid mine drainage from metals extraction or natural acid rock drainage and its mixing with surface waters is a complex process that depends on petrology and mineralogy, structural geology, geomorphology, surface-water hydrology, hydrogeology, climatology, microbiology, chemistry, and mining and mineral processing history. The concentrations of metals, metalloids...
Authors
D. Kirk Nordstrom
Water-chemistry data for selected springs, geysers, and streams in Yellowstone National Park, Wyoming, 2006-2008 Water-chemistry data for selected springs, geysers, and streams in Yellowstone National Park, Wyoming, 2006-2008
Water analyses are reported for 104 samples collected from numerous thermal and non-thermal features in Yellowstone National Park (YNP) during 2006-2008. Water samples were collected and analyzed for major and trace constituents from 10 areas of YNP including Apollinaris Spring and Nymphy Creek along the Norris-Mammoth corridor, Beryl Spring in Gibbon Canyon, Norris Geyser Basin, Lower...
Authors
James W. Ball, R. Blaine McMleskey, D. Kirk Nordstrom
Science and Products
Filter Total Items: 164
Solute and geothermal flux monitoring using electrical conductivity in the Madison, Firehole, and Gibbon Rivers, Yellowstone National Park Solute and geothermal flux monitoring using electrical conductivity in the Madison, Firehole, and Gibbon Rivers, Yellowstone National Park
The thermal output from the Yellowstone magma chamber can be estimated from the Cl flux in the major rivers in Yellowstone National Park; and by utilizing continuous discharge and electrical conductivity measurements the Cl flux can be calculated. The relationship between electrical conductivity and concentrations of Cl and other geothermal solutes (Na, SO4, F, HCO3, SiO2, K, Li, B, and...
Authors
R. Blaine McCleskey, Laura Clor, Jacob B. Lowenstern, William C. Evans, D. Kirk Nordstrom, Henry Heasler, Mark Huebner
Models, validation, and applied geochemistry: Issues in science, communication, and philosophy Models, validation, and applied geochemistry: Issues in science, communication, and philosophy
Models have become so fashionable that many scientists and engineers cannot imagine working without them. The predominant use of computer codes to execute model calculations has blurred the distinction between code and model. The recent controversy regarding model validation has brought into question what we mean by a ‘model’ and by ‘validation.’ It has become apparent that the usual...
Authors
D. Kirk Nordstrom
Simultaneous oxidation of arsenic and antimony at low and circumneutral pH, with and without microbial catalysis Simultaneous oxidation of arsenic and antimony at low and circumneutral pH, with and without microbial catalysis
Arsenic and Sb are common mine-water pollutants and their toxicity and fate are strongly influenced by redox processes. In this study, simultaneous Fe(II), As(III) and Sb(III) oxidation experiments were conducted to obtain rates under laboratory conditions similar to those found in the field for mine waters of both low and circumneutral pH. Additional experiments were performed under...
Authors
Maria P. Asta, D. Kirk Nordstrom, R. Blaine McCleskey
A new method of calculating electrical conductivity with applications to natural waters A new method of calculating electrical conductivity with applications to natural waters
A new method is presented for calculating the electrical conductivity of natural waters that is accurate over a large range of effective ionic strength (0.0004–0.7 mol kg−1), temperature (0–95 °C), pH (1–10), and conductivity (30–70,000 μS cm−1). The method incorporates a reliable set of equations to calculate the ionic molal conductivities of cations and anions (H+, Li+, Na+, K+, Cs+...
Authors
R. Blaine McCleskey, D. Kirk Nordstrom, J. N. Ryan, J. W. Ball
Comparison of electrical conductivity calculation methods for natural waters Comparison of electrical conductivity calculation methods for natural waters
The capability of eleven methods to calculate the electrical conductivity of a wide range of natural waters from their chemical composition was investigated. A brief summary of each method is presented including equations to calculate the conductivities of individual ions, the ions incorporated, and the method's limitations. The ability of each method to reliably predict the conductivity...
Authors
R. Blaine McCleskey, D. Kirk Nordstrom, Joseph N. Ryan
Mine waters: Acidic to circumneutral Mine waters: Acidic to circumneutral
Acid mine waters, often containing toxic concentrations of Fe, Al, Cu, Zn, Cd, Pb, Ni, Co, and Cr, can be produced from the mining of coal and metallic deposits. Values of pH for acid mine waters can range from –3.5 to 5, but even circumneutral (pH ≈ 7) mine waters can have high concentrations of As, Sb, Mo, U, and F. When mine waters are discharged into streams, lakes, and the oceans...
Authors
D. Kirk Nordstrom
Sulfide mineral oxidation Sulfide mineral oxidation
No abstract available.
Authors
D. Kirk Nordstrom
Fluoride geochemistry of thermal waters in Yellowstone National Park: I. Aqueous fluoride speciation Fluoride geochemistry of thermal waters in Yellowstone National Park: I. Aqueous fluoride speciation
Thermal water samples from Yellowstone National Park (YNP) have a wide range of pH (1–10), temperature, and high concentrations of fluoride (up to 50 mg/l). High fluoride concentrations are found in waters with field pH higher than 6 (except those in Crater Hills) and temperatures higher than 50 °C based on data from more than 750 water samples covering most thermal areas in YNP from...
Authors
Y. Deng, D. Kirk Nordstrom, R. Blaine McCleskey
Ammonium in thermal waters of Yellowstone National Park: Processes affecting speciation and isotope fractionation Ammonium in thermal waters of Yellowstone National Park: Processes affecting speciation and isotope fractionation
Dissolved inorganic nitrogen, largely in reduced form (NH4(T)≈NH4(aq)++NH3(aq)o), has been documented in thermal waters throughout Yellowstone National Park, with concentrations ranging from a few micromolar along the Firehole River to millimolar concentrations at Washburn Hot Springs. Indirect evidence from rock nitrogen analyses and previous work on organic compounds associated with...
Authors
J.M. Holloway, D. Kirk Nordstrom, J.K. Böhlke, R. Blaine McCleskey, J.W. Ball
Quality of our groundwater resources: Arsenic and fluoride Quality of our groundwater resources: Arsenic and fluoride
Groundwater often contains arsenic or fluoride concentrations too high for drinking or cooking. These constituents, often naturally occurring, are not easy to remove. The right combination of natural or manmade conditions can lead to elevated arsenic or fluoride which includes continental source rocks, high alkalinity and pH, reducing conditions for arsenic, high phosphate, high...
Authors
D. Kirk Nordstrom
Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters Hydrogeochemical processes governing the origin, transport and fate of major and trace elements from mine wastes and mineralized rock to surface waters
The formation of acid mine drainage from metals extraction or natural acid rock drainage and its mixing with surface waters is a complex process that depends on petrology and mineralogy, structural geology, geomorphology, surface-water hydrology, hydrogeology, climatology, microbiology, chemistry, and mining and mineral processing history. The concentrations of metals, metalloids...
Authors
D. Kirk Nordstrom
Water-chemistry data for selected springs, geysers, and streams in Yellowstone National Park, Wyoming, 2006-2008 Water-chemistry data for selected springs, geysers, and streams in Yellowstone National Park, Wyoming, 2006-2008
Water analyses are reported for 104 samples collected from numerous thermal and non-thermal features in Yellowstone National Park (YNP) during 2006-2008. Water samples were collected and analyzed for major and trace constituents from 10 areas of YNP including Apollinaris Spring and Nymphy Creek along the Norris-Mammoth corridor, Beryl Spring in Gibbon Canyon, Norris Geyser Basin, Lower...
Authors
James W. Ball, R. Blaine McMleskey, D. Kirk Nordstrom
*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government