Madalyn S. Blondes, Ph.D.
Madalyn Blondes is a Research Geologist at the USGS Geology, Energy & Minerals (GEM) Science Center in Reston, VA.
Madalyn is the co-Chief of the Oil & Gas Waters Project and also works on the Utilization of Carbon and other Energy Gases Project. Her current research focuses on the geochemistry of water associated with oil and gas production (produced waters), geologic CO2 storage through mineralization, compositional data analysis (CoDa) in the earth sciences, development of probabilistic assessment methodologies for CO2 storage and enhanced oil recovery (EOR) in geologic reservoirs, and using geochemistry to understand CO2 flow in natural systems. Madalyn obtained her B.A. from the Pomona College Geology Department in 2003 and her Ph.D. from the Yale University Department of Geology & Geophysics in 2008. She did postdoctoral research at the University of Maryland before joining the USGS in 2010.
Professional Experience
2008 - 2010: Postdoctoral Associate, University of Maryland, College Park, MD
Education and Certifications
Ph.D. Geology & Geophysics, Yale University, 2008
M.Phil. Geology & Geophysics, Yale University, 2005
B.A. Geology, Pomona College, 2003
Science and Products
Oil and Gas Waters Project
Characterization and Reuse of Oil and Gas Waters
Lithium observations, machine-learning predictions, and mass estimates from the Smackover Formation brines in southern Arkansas
Carbon Dioxide Storage Resources - Appalachian Basin, Black Warrior Basin, Illinois Basin, and Michigan Basin: Chapter P, Spatial Data
Utica Shale and Point Pleasant Formation Isotopic Compositions
Carbon Dioxide Storage Resources-Wind River Basin: Chapter O, Spatial Data
U.S. Geological Survey National Produced Waters Geochemical Database (ver. 3.0, December 2023)
Absorbance and Fluorescence Excitation-Emission Matrix Data for Produced Waters from Oil and Gas Producing Basins in the United States
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources - data release
Geologic formations and mine locations for potential CO2 mineralization
Microbiology of the Utica Shale
Input Files and Code for: Machine learning can accurately assign geologic basin to produced water samples using major geochemical parameters
Model of groundwater flow, gas migration, and reactive transport in the Virgin River Basin, SW Utah
Geochemistry of Utica Shale Play and other Appalachian produced waters
Utica/Point Pleasant brine isotopic compositions (δ7Li, δ11B, δ138Ba) elucidate mechanisms of lithium enrichment in the Appalachian Basin
Ion exchange processes for CO2 mineralization using industrial waste streams: Pilot plant demonstration and life cycle assessment
Geologic carbon management options for the North Atlantic-Appalachian Region
Dissolved organic matter within oil and gas associated wastewaters from U.S. unconventional petroleum plays: Comparisons and consequences for disposal and reuse
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources — Results
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources — Summary
Machine learning can assign geologic basin to produced water samples using major ion geochemistry
Potential Pb+2 mobilization, transport, and sequestration in shallow aquifers impacted by multiphase CO2 leakage: A natural analogue study from the Virgin River Basin in Southwest Utah
Utica shale play oil and gas brines: Geochemistry and factors influencing wastewater management
The Utica and Marcellus Shale Plays in the Appalachian Basin are the fourth and first largest natural gas producing plays in the United States, respectively. Hydrocarbon production generates large volumes of brine (“produced water”) that must be disposed of, treated, or reused. Though Marcellus brines have been studied extensively, there are few studies from the Utica Shale Play. This study presen
Four-dimensional thermal evolution of the East African Orogen: Accessory phase petrochronology of crustal profiles through the Tanzanian Craton and Mozambique Belt, northeastern Tanzania
Repetitive sampling and control threshold improve 16S rRNA results from produced waters associated with hydraulically fractured shales
Modeling geologic sequestration of carbon dioxide in a deep saline carbonate reservoir with TOUGH2–ChemPlugin, a new tool for reactive transport modeling
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
U.S. Geological Survey National Produced Waters Geochemical Database (ver. 3.0, December 2023) Viewer
The U.S. Geological Survey National Produced Waters Geochemical Database Viewer (ver. 3.0) provides access to an updated compilation of geochemical and related information for water from oil and gas wells in the United States. The information includes identification and location information, well descriptions, dates, rock properties, physical properties of the water, organic chemistry and more.
CO2assessment R package
Science and Products
Oil and Gas Waters Project
Characterization and Reuse of Oil and Gas Waters
Lithium observations, machine-learning predictions, and mass estimates from the Smackover Formation brines in southern Arkansas
Carbon Dioxide Storage Resources - Appalachian Basin, Black Warrior Basin, Illinois Basin, and Michigan Basin: Chapter P, Spatial Data
Utica Shale and Point Pleasant Formation Isotopic Compositions
Carbon Dioxide Storage Resources-Wind River Basin: Chapter O, Spatial Data
U.S. Geological Survey National Produced Waters Geochemical Database (ver. 3.0, December 2023)
Absorbance and Fluorescence Excitation-Emission Matrix Data for Produced Waters from Oil and Gas Producing Basins in the United States
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources - data release
Geologic formations and mine locations for potential CO2 mineralization
Microbiology of the Utica Shale
Input Files and Code for: Machine learning can accurately assign geologic basin to produced water samples using major geochemical parameters
Model of groundwater flow, gas migration, and reactive transport in the Virgin River Basin, SW Utah
Geochemistry of Utica Shale Play and other Appalachian produced waters
Utica/Point Pleasant brine isotopic compositions (δ7Li, δ11B, δ138Ba) elucidate mechanisms of lithium enrichment in the Appalachian Basin
Ion exchange processes for CO2 mineralization using industrial waste streams: Pilot plant demonstration and life cycle assessment
Geologic carbon management options for the North Atlantic-Appalachian Region
Dissolved organic matter within oil and gas associated wastewaters from U.S. unconventional petroleum plays: Comparisons and consequences for disposal and reuse
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources — Results
National assessment of carbon dioxide enhanced oil recovery and associated carbon dioxide retention resources — Summary
Machine learning can assign geologic basin to produced water samples using major ion geochemistry
Potential Pb+2 mobilization, transport, and sequestration in shallow aquifers impacted by multiphase CO2 leakage: A natural analogue study from the Virgin River Basin in Southwest Utah
Utica shale play oil and gas brines: Geochemistry and factors influencing wastewater management
The Utica and Marcellus Shale Plays in the Appalachian Basin are the fourth and first largest natural gas producing plays in the United States, respectively. Hydrocarbon production generates large volumes of brine (“produced water”) that must be disposed of, treated, or reused. Though Marcellus brines have been studied extensively, there are few studies from the Utica Shale Play. This study presen
Four-dimensional thermal evolution of the East African Orogen: Accessory phase petrochronology of crustal profiles through the Tanzanian Craton and Mozambique Belt, northeastern Tanzania
Repetitive sampling and control threshold improve 16S rRNA results from produced waters associated with hydraulically fractured shales
Modeling geologic sequestration of carbon dioxide in a deep saline carbonate reservoir with TOUGH2–ChemPlugin, a new tool for reactive transport modeling
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
U.S. Geological Survey National Produced Waters Geochemical Database (ver. 3.0, December 2023) Viewer
The U.S. Geological Survey National Produced Waters Geochemical Database Viewer (ver. 3.0) provides access to an updated compilation of geochemical and related information for water from oil and gas wells in the United States. The information includes identification and location information, well descriptions, dates, rock properties, physical properties of the water, organic chemistry and more.