Assessment of the Subsurface Pathogen Abatement Effects of Nutrient Management Policy in Ontario

The transport mechanisms of pathogens through the subsurfact environment are complex. Provincial legislation, such as Ontario's Nutrient Management Act (2002) is designed to control nutrients in agricultural settings and it is assumed that the Act also attempts to control pathogens from reaching source waters. The study examined the progressive restrictions on agricultural practices that are sources of pathogens in water. Furthermore, current research in microbial subsurface transport and modelling was examined to determine if existing legislation is sufficient in controlling pathogens. Analysis showed that research gaps in microbial subsurface transport studies restricts subsurface research and transport models from effectively predicting the fate of pathogens. Furthermore, gaps in research restrict nutrient management legislation from protecting source waters from pathogens. Research showed that a 'critical control point' strategy that acts to decrease pathogen loading to agricultural surfaces is key in reducing the risks that microorganisms pose to ground water sources.

Assessment of the Subsurface Pathogen Abatement Effects of Nutrient Management Policy in Ontario

The transport mechanisms of pathogens through the subsurfact environment are complex. Provincial legislation, such as Ontario's Nutrient Management Act (2002) is designed to control nutrients in agricultural settings and it is assumed that the Act also attempts to control pathogens from reaching source waters. The study examined the progressive restrictions on agricultural practices that are sources of pathogens in water. Furthermore, current research in microbial subsurface transport and modelling was examined to determine if existing legislation is sufficient in controlling pathogens. Analysis showed that research gaps in microbial subsurface transport studies restricts subsurface research and transport models from effectively predicting the fate of pathogens. Furthermore, gaps in research restrict nutrient management legislation from protecting source waters from pathogens. Research showed that a 'critical control point' strategy that acts to decrease pathogen loading to agricultural surfaces is key in reducing the risks that microorganisms pose to ground water sources.

Migration and storage of methane in the Martian crust

<p>Several detections of methane in the Martian atmosphere have been reported from Earth-based and Mars orbit instruments with abundances ranging up to tens of ppbv, while in-situ measurements performed by the MSL rover at Gale crater showed some peaks up to 7 ppbv. A variety of methane formation mechanisms occurring in the subsurface have been proposed such as abiotic synthesis through Fischer-Tropsch Type (FTT) reactions. After its generation at depth, Martian methane can migrate upwards and be either directly released at the surface or trapped in subsurface reservoirs, such as clathrate hydrates, where it could accumulate over long time before being episodically liberated during destabilizing events. When ascending through stratigraphic layers, methane can move via one or several transport mechanisms. Seepage can occur through advection, the main CH<sub>4</sub> transport process on Earth, driven by pressure gradients and permeability and generally associated to fracture networks. Another transport mechanism is diffusion, which is mainly controlled by concentration gradient. This process is not efficient on short timescales and short-lived methane plumes related to diffusion should therefore originate from very shallow depths.</p><p>In this work, we model the subsurface transport of methane on Mars and its subsequent trapping in clathrate hydrates. For the latter, the effect of the clathrate formation pressure is especially examined, while methane subsurface transport is studied considering adsorption onto, advection and diffusion through the regolith.</p>