Abstract
Methane contamination of drinking water resources is one of the major concerns associated with unconventional gas development. This study assesses the potential contamination of shallow groundwater via methane migration from a leaky natural gas well through overburden rocks, following hydraulic fracturing. A two-dimensional, two-phase, two-component numerical model is employed to simulate methane and brine upward migration toward shallow groundwater in a generic sedimentary basin. A sensitivity analysis is conducted to examine the influence of methane solubility, capillary pressure–saturation relationship parameters and residual water saturation of overburden rocks, gas leakage rate from the well, tilted formations, and low-permeability sediments (i.e., claystones) on the transport of fluids. Results show that the presence of lithological barriers is the most important factor controlling the temporal–spatial distribution of methane in the subsurface and the arrival time to shallow groundwater. A pulse of high leakage rate is required for early manifestation of methane in groundwater wells. Simulations reveal that the presence of tilted features could further explain fast-growing methane contamination and extensive lateral spreading reported in field studies.
Highlights
The global demand for energy is continuously increasing around the world and the International Energy Agency (IEA) anticipated more than 25% of growth by 2040 (IEA 2018)
Of the potential mechanisms identified, the focus of this study is on fugitive gas and brine migration from a leaky natural gas well through overburden rocks towards shallow groundwater
We focus on the role of low-permeability sediments, tilted formations, and methane leakage rates and periods on the transport of methane to shallow subsurface
Summary
The global demand for energy is continuously increasing around the world and the International Energy Agency (IEA) anticipated more than 25% of growth by 2040 (IEA 2018). Natural gas production from unconventional resources is considered as a promising future source for energy supply as a bridge fuel toward a low-carbon energy system (Brown et al 2009; McGlade et al 2013). Natural gas is mainly composed of methane with a small amount of carbon dioxide, oxygen, nitrogen, and hydrogen sulfide. Methane in stream flows and groundwater is either of biogenic and thermogenic origin. Biogenic methane is produced by microbiological processes from in situ fermentation or reduction of carbon dioxide. Thermogenic methane is derived from the upward migration of natural gas associated with deep hydrocarbon formations (Gorody 2012; Darrah et al 2015).
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