INVESTIGATION OF GROUNDWATER CONTAMINATION RISK INDUCED BY ANTHROPOGENIC ACTIVITIES

Groundwater is a crucial freshwater resource utilized for daily human activities, particularly in regions characterized by semi-arid or arid conditions. Nevertheless, the continuous development of society and technology has led to substantial anthropogenic influences on the groundwater environment, resulting in a decline in groundwater quality. Previous studies have primarily focused on comprehending the processes of groundwater contamination considering groundwater contamination as a static, steady-state condition, largely overlooking the dynamic changes caused by anthropogenic activities. Also, the variation of influence of each factor on groundwater quality was ignored. Consequently, the primary objective of this thesis is to investigate how anthropogenic activities under diverse conditions alter the susceptibility of groundwater to contamination. Nitrate, a commonly occurring contaminant in groundwater, is utilized as an illustrative example.

The study first reveals that the influences of anthropogenic nitrogen inputs on the susceptibility of groundwater to contamination resulting from agricultural, livestock, and urbanization activities are larger than the physical-related factors. Furthermore, the accumulation of contaminants from historical practices can result in long-term contamination as significant time lags exist between the implementation of management practices and improvements in groundwater quality. Building upon the assessment of each contributing factor, a redefined index-based methodology is proposed, enabling accurate predictions of the likelihood of groundwater contamination with limited available information, and achieving an accuracy rate of 70% under varying environmental conditions. In addition to nonpoint source contamination originating from terrestrial sources, the study also explores the potential influence of riverine systems on groundwater quality. Considerable area-weighted nitrogen leakage fluxes from rivers are frequently observed in regions with losing streams. The interconnected network of streams across the continental United States (CONUS) enables the transport and accumulation of contaminants from local sources to uncontaminated areas, thereby expanding the regions susceptible to groundwater contamination. Furthermore, while agricultural activities are the primary contributors of nitrate contamination in groundwater, the study identifies an increasing impact of livestock production on groundwater nitrate concentrations. Changes in dietary habits have the potential for reducing the susceptibility of groundwater to contamination. The study quantifies the resource requirements and environmental effects associated with conventional meat products and compares them with alternative meat products. Life cycle analyses indicate that cultured meat products have the lowest resource requirements, and scenarios involving the substitution of meat alternatives exhibit significant mitigation effects on groundwater nitrate contamination.

To summarize, this thesis contributes to the understanding of dynamic groundwater contamination risks and the varying impacts resulting from anthropogenic activities, extending beyond the traditional focus on steady-state conditions. It introduces an advanced methodology for better comprehending and assessing dynamic groundwater contamination risks, while also conducting comprehensive analyses of the influences of agriculture, livestock, and riverine systems.

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