Abstract
Regulators require the gas industry to assess the risks of unintentional release of chemicals to the environment and implement measures to mitigate it. Industry standard models for contaminant transport in aquifers do not explicitly model processes in the unsaturated zone and groundwater models often require long run times to complete simulation of complex processes. We propose a stochastic numerical-analytical hybrid model to overcome these two shortcomings and demonstrate its application to assess the risks associated with onshore gas drilling in the Otway Basin, South Australia. The novel approach couples HYDRUS-1D to an analytical solution to model contaminant transport in the aquifer. Groundwater velocities and chemical trajectories were derived from a particle tracking analysis. The most influential parameters controlling solute delivery to the aquifer were the soil chemical degradation constant and the hydraulic conductivity of a throttle soil horizon. Only 18% of the flow paths intercepted environmental receptors within a 1-km radius from the source, 87% of which had concentrations of <1% of the source. The proposed methodology assesses the risk to environmental assets and informs regulators to implement measures that mitigate risk down to an acceptable level.
Highlights
Industrial, agricultural and aviation activities require appropriate management measures and regulatory controls to avoid uncontrolled release of chemicals to the environment (Brantley et al, 2014; Cousins et al, 2016; Wu and Sun, 2016)
Transport through the saturated zone (Step 2) was carried out using a novel solute transport modelling approach, which involves three stages: (2a) numerical groundwater modelling to identify flow rates along plausible flow paths throughout the aquifer, (2b) a spatial analysis to identify the lengths of the flow paths that intercepted groundwater-dependent receptors, and (2c) one-dimensional analytical modelling of advective-dispersive solute transport under steady-state flow using the outputs from Steps (2a and 2b) to identify peak concentrations at the interception points with receptors
The HYDRUS-1D stochastic simulations produced one thousand breakthrough curves, which describe the solute flux at the lower boundary of the flow domain
Summary
Industrial, agricultural and aviation activities require appropriate management measures and regulatory controls to avoid uncontrolled release of chemicals to the environment (Brantley et al, 2014; Cousins et al, 2016; Wu and Sun, 2016). Stochastic Modelling and Risk Assessment contamination resulting from surface handling of chemicals associated with conventional gas developments. Despite stringent industry and regulatory standard procedures that ensure minimal likelihood of environmental hazards, activities associated with onshore gas developments may lead to water contamination risks (Mallants et al, 2018, 2020). Flow in the unsaturated zone (Step 1; encircled “1” in Figure 2) involved the use of a 1D-numerical model to simulate transient vertical leaching of solutes from the surface (point of contamination) through the soil to the groundwater table.
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