Megan K. Dustin scite author profile

Hydraulic fracturing of unconventional hydrocarbon reservoirs is critical to the United States energy portfolio; however, hydrocarbon production from newly fractured wells generally declines rapidly over the initial months of production. One possible reason for this decrease, especially over time scales of several months, is the mineralization and clogging of microfracture networks and pores proximal to propped fractures. One important but relatively unexplored class of reactions that could contribute to these problems is oxidation of Fe(II) derived from Fe(II)-bearing phases (primarily pyrite, siderite, and Fe(II) bound directly to organic matter) by the oxic fracture fluid and subsequent precipitation of Fe(III)-(oxy)hydroxides. The extent to which such reactions occur and their rates, mineral products, and physical locations within shale pore spaces are unknown. To develop a foundational understanding of potential impacts of shale iron chemistry on hydraulic stimulation, we reacted sand-sized (150-250 μm) and whole rock chips (cm-scale) of shales from four different formations

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Element release and reaction-induced porosity alteration during shale-hydraulic fracturing fluid interactions

Harrison

Jew

Dustin

et al. 2017

Applied Geochemistry

115

178

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Shale Kerogen: Hydraulic Fracturing Fluid Interactions and Contaminant Release

et al. 2018

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The recent increase in unconventional oil and gas exploration and production has prompted a large amount of research on hydraulic fracturing, but the majority of chemical reactions between shale minerals and organic matter with fracturing fluids are not well understood. Organic matter, primarily in the form of kerogen, dominates the transport pathways for oil and gas; thus any alteration of kerogen (both physical and chemical properties) upon exposure to fracturing fluid may impact hydrocarbon extraction. In addition, kerogen is enriched in metals, making it a potential source of heavy metal contaminants to produced waters. In this study, we reacted two different kerogen isolates of contrasting type and maturity (derived from Green River and Marcellus shales) with a synthetic hydraulic fracturing fluid for 2 weeks in order to determine the effect of fracturing fluids on both shale organic matter and closely associated minerals. ATR-FTIR results show that the functional group compositions of the kerogen isolates were in fact altered, although by apparently different mechanisms. In particular, hydrophobic functional groups decreased in the Marcellus kerogen, which suggests the wettability of shale organic matter may be susceptible to alteration during hydraulic fracturing operations. About 1% of organic carbon in the more immature and Type I Green River kerogen isolate was solubilized when it was exposed to fracturing fluid, and the released organic compounds significantly impacted Fe oxidation. On the basis of the alteration observed in both kerogen isolates, it should not be assumed that kerogenic pores are chemically inert over the time frame of hydraulic fracturing operations. Shifts in functional group composition and loss of hydrophobicity have the potential to degrade transport and storage parameters such as wettability, which could alter hydrocarbon and fracturing fluid transport through shale. Additionally, reaction of Green River and Marcellus kerogen isolates with low pH solutions (full fracturing fluid, which contains hydrochloric acid, or pH 2 water) mobilized potential trace metal(loid) contaminants, primarily S, Fe, Co, Ni, Zn, and Pb. The source of trace metal(loid)s varied between the two kerogen isolates, with metals in the Marcellus shale largely sourced from pyrite impurities, whereas metals in the Green River shale were sourced from a combination of accessory minerals and kerogen.

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Mineralogical and Porosity Alteration Following Fracture Fluid-Shale Reaction

Jew¹,

Harrison²,

Dustin³

et al. 2017

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Effects of ionic liquid media on the cation selectivity of uranyl structural units in five new compounds produced using the ionothermal technique

et al. 2014

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Thermodynamic investigation of uranyl vanadate minerals: Implications for structural stability

Spano

Dzik

Sharifironizi

et al. 2017

American Mineralogist

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Ionothermal synthesis of uranyl compounds that incorporate imidazole derivatives

Wylie

Dustin

Smith

et al. 2013

Journal of Solid State Chemistry

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Policy: Reassess New Mexico's nuclear-waste repository

Tracy

Dustin

Ewing

2016

Nature

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Megan K. Dustin

Impact of Organics and Carbonates on the Oxidation and Precipitation of Iron during Hydraulic Fracturing of Shale

Element release and reaction-induced porosity alteration during shale-hydraulic fracturing fluid interactions

Shale Kerogen: Hydraulic Fracturing Fluid Interactions and Contaminant Release

Mineralogical and Porosity Alteration Following Fracture Fluid-Shale Reaction

Effects of ionic liquid media on the cation selectivity of uranyl structural units in five new compounds produced using the ionothermal technique

Thermodynamic investigation of uranyl vanadate minerals: Implications for structural stability

Ionothermal synthesis of uranyl compounds that incorporate imidazole derivatives

Policy: Reassess New Mexico's nuclear-waste repository

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