Project Abstract

This project aims to explore the phytoremediation potential of indigenous plant species for the remediation of heavy metal-contaminated soils. Soil contamination by heavy metals is a growing concern worldwide, posing significant threats to human health and the environment. Conventional remediation methods, such as physical and chemical treatments, can be costly, invasive, and often have limited long-term effectiveness. Phytoremediation, the use of plants to remove, degrade, or stabilize contaminants, has emerged as a promising eco-friendly and cost-effective alternative. The project focuses on identifying and evaluating the phytoremediation capabilities of indigenous plant species native to the study region. These plants, adapted to the local climate and soil conditions, are hypothesized to have developed enhanced mechanisms for heavy metal tolerance and accumulation, making them ideal candidates for in-situ remediation. The study will contribute to a better understanding of the phytoremediation potential of underutilized indigenous plant resources and their application in restoring degraded ecosystems. The primary objectives of this project are to 1) conduct a comprehensive assessment of heavy metal contamination levels in the target soil samples; 2) screen and select indigenous plant species with high phytoremediation potential based on their growth performance, metal accumulation, and tolerance abilities; 3) evaluate the mechanistic underpinnings of the plant-metal interactions, including metal uptake, translocation, and sequestration strategies; and 4) develop optimized phytoremediation protocols for the most promising indigenous plant species. The project will employ a multi-pronged approach, combining field surveys, greenhouse experiments, and laboratory analyses. Field surveys will be conducted to identify and collect soil and plant samples from contaminated sites, as well as from uncontaminated reference areas. Greenhouse experiments will be designed to assess the growth, metal accumulation, and tolerance of the selected indigenous plant species under controlled conditions. Advanced analytical techniques, such as atomic absorption spectroscopy, scanning electron microscopy, and X-ray diffraction, will be used to elucidate the metal uptake, translocation, and sequestration mechanisms within the plants. The findings of this project will contribute to the scientific knowledge on the phytoremediation potential of indigenous plant species and their application in addressing heavy metal-contaminated soils. The outcomes will inform the development of site-specific, sustainable, and cost-effective phytoremediation strategies that can be implemented to restore degraded ecosystems and mitigate the risks posed by heavy metal pollution. Furthermore, the project will highlight the value of conserving and utilizing indigenous plant resources for environmental remediation, fostering a more holistic approach to ecosystem management and restoration. The successful completion of this project will have significant implications for environmental protection, sustainable land use, and the development of nature-based solutions for soil remediation. By leveraging the inherent capabilities of indigenous plant species, this research will pave the way for the widespread adoption of phytoremediation as a viable and eco-friendly alternative to conventional remediation methods, ultimately contributing to the creation of a healthier and more resilient environment.

Project Overview