Thesis Abstract

**Abstract
** Industrial activities release heavy metals into wastewater, posing significant environmental and health risks. This study aimed to determine the extent of heavy metal contamination in industrial wastewater and evaluate treatment methods to mitigate these pollutants. The research focused on the identification of heavy metal concentrations, sources of contamination, and the effectiveness of treatment technologies in reducing metal levels to permissible limits. Various analytical techniques, such as atomic absorption spectroscopy and X-ray fluorescence analysis, were employed to quantify heavy metal concentrations in wastewater samples from different industrial sources. The literature review highlighted the adverse effects of heavy metal pollution on ecosystems and human health, emphasizing the need for effective treatment strategies. The research methodology encompassed sampling procedures, experimental setups, and data analysis methods used to assess heavy metal removal efficiency. Treatment methods investigated included physical, chemical, and biological processes, such as precipitation, ion exchange, adsorption, and phytoremediation. Results from the study demonstrated varying levels of heavy metal contamination in industrial wastewater, with lead, cadmium, mercury, and chromium being the most prevalent pollutants. Treatment trials revealed that a combination of physical and chemical processes, such as coagulation-flocculation followed by activated carbon adsorption, effectively reduced heavy metal concentrations to below regulatory limits. Additionally, the use of plant-based systems, such as constructed wetlands, showed promising results in removing heavy metals from contaminated wastewater. The discussion of findings highlighted the importance of selecting appropriate treatment methods based on specific heavy metal characteristics and wastewater compositions. Factors influencing treatment efficiency, such as pH, temperature, contact time, and initial metal concentrations, were thoroughly examined to optimize remediation processes. The study concluded that a combination of treatment technologies tailored to the unique characteristics of industrial wastewater is essential for achieving successful heavy metal removal. In summary, this research contributes to the understanding of heavy metal contamination in industrial wastewater and provides valuable insights into the selection and optimization of treatment methods for mitigating the environmental and health risks associated with heavy metal pollution. The findings of this study can guide industries, regulatory bodies, and environmental practitioners in developing sustainable solutions to address heavy metal contamination in industrial wastewater and safeguard water resources for future generations.

Thesis Overview