We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Potential Toxic-Element Pollution in Surface Water and Its Implications for Aquatic and Human Health: Source–Pathway–Receptor Model
Summary
Researchers assessed toxic element pollution in surface water near gold mining operations in South Africa, finding elevated levels of heavy metals that pose risks to both aquatic life and human health. They used a source-pathway-receptor model to trace how pollutants from mine tailings move through the environment. The study highlights the significant water quality threats that mining activities create for surrounding communities and ecosystems.
This study focused on assessing the extent of pollution in both flowing and non-flowing surface water within the Matjhabeng mining area of South Africa, with particular emphasis on the substantial impact of gold mine tailings. A comprehensive analysis of physical water-quality attributes, including potentially toxic elements (PTEs), and relevant pollution risk indices was undertaken. To comprehensively elucidate the potential risks to aquatic organisms and human health, a risk assessment framework predicated upon the source–pathway–receptor model was developed. Principal Component Analysis (PCA) was employed as a multivariate statistical tool to discern the potential origins of PTE contamination within the environment. The results substantiate pronounced pollution manifestations within the surface water milieu of the Matjhabeng mining area. Specifically, concentrations of critical PTEs, such as arsenic, cobalt, copper, iron, selenium, and zinc, exhibited transgressions of the regulatory thresholds stipulated by both the South African Department of Water Affairs and Forestry (DWAF) and the Canadian Council of the Ministers of the Environment (CCME). Additionally, concentrations of the aforementioned elements exceeded the stipulated DWAF guidelines for irrigation water usage. Pollution indices, encompassing the Single-Factor Pollution Index and the Nemerow Integrated Pollution Index, discerned moderate contamination stemming from As, while remarkably elevated pollution levels were identified for selenium. PCA elucidated 94.5% of the aggregate variance, revealing cobalt, copper, nickel, and zinc as coalescing within PC1, indicative of a common anthropogenic provenance that is conceivably linked to historical gold mine tailings. PC2 exhibited an aggregation of chromium, iron, and lead, reaffirming this shared anthropogenic etiology. The third PCA component was characterized by selenium, followed by arsenic and magnesium in the fourth. The resultant PTE contamination underscores a profound ecological and public health risk, impacting both the aquatic ecosystems and the local community within the precincts of the Matjhabeng Local Municipality (MLM) area, with consequential amplification of susceptibilities to deleterious health consequences. Urgent and concerted interventions are imperative to ameliorate the emergent decline in surface-water quality within the MLM locale. The adoption of nature-based remediation paradigms holds promise for efficaciously elevating water quality, ameliorating community health, and underpinning the long-term economic viability of the region.
Sign in to start a discussion.
More Papers Like This
Microplastics exacerbate heavy metal pollution stress in the surface water of a mining city: Occurrence, drivers, and vector effects
Researchers studied the co-occurrence of microplastics and heavy metals in surface water of a coal mining city and found that microplastics act as vectors that exacerbate heavy metal transport and pollution. The study identified key drivers of combined contamination from mining activities, farmland reclamation, and urban runoff. The findings suggest that microplastics in mining regions amplify the environmental risks of heavy metal pollution by carrying and concentrating toxic metals.
Risk assessment and source apportionment of trace elements in multiple compartments in the lower reach of the Jinsha River, China
Researchers analyzed six trace element pollutants across water, sediment, and soil in a 28-km river stretch in China and found that industrial and agricultural activities were the main sources, with ingestion being the top health risk pathway — highlighting the need to assess connected environmental systems together rather than in isolation.
The Impact of Industrialization, Urbanization, and Drought on Heavy Metal Contamination in River Systems in Kwazulu-natal, South Africa: a Cross-sectional Study.
This cross-sectional study in KwaZulu-Natal, South Africa investigated how industrialization, urbanization, and drought interact to drive heavy metal contamination in river systems, finding that low water levels during drought amplify pollutant concentrations.
Health Risks from Intake and Contact with Toxic Metal-Contaminated Water from Pager River, Uganda
Researchers investigated the concentrations of lead and cadmium in the Pager River in Uganda, a tributary of the Nile, and assessed associated human health risks. The study found that water from certain sampling points posed potential health risks through both ingestion and skin contact, highlighting the importance of monitoring toxic metals in water sources used by local communities.
Emission and fate modelling framework for engineered nanoparticles in urban aquatic systems at high spatial and temporal resolution
Researchers developed a combined emission and fate modelling framework to improve exposure assessment of engineered nanoparticles in complex urban aquatic systems at high spatial and temporal resolution.