Ecological Disturbances and Adaptation of Mangroves in High-Disturbance Urban Areas of Navi Mumbai in India
Abstract
Mangroves are coastal ecosystems characterized by salt-tolerant intertidal forest structures that serve as vital buffer zones between the coastal waters and human habitats. They expose an evolutionary course spanning around 60 million years, leading to the emergence of tailored adaptations like salt-excreting glands and prop roots. Despite widespread acknowledgment of their value, mangroves are swiftly declining due to coastal development and climate change. Rapid urbanization has increased anthropogenic pressures on these ecosystems, yet comprehensive assessments of their resilience in highly disturbed environments remain limited. This study looks at the ecological health of mangrove populations across three sites in Navi Mumbai, areas facing high urban and industrial growth. The analysis revealed elevated Zn (-0.88, p < 0.001), Cu (-0.73, p < 0.01), Pb (-0.70, p < 0.05), and Mn (-0.76, p < 0.01) correlating with reduced plant height, alongside consistently acidic water pH (mean = 5.93) and high salinity (range: 35–40 PSU). These conditions amplify metal mobility and toxicity, disrupting pneumatophore function, and lowering DO (mean = 3.8 mg/L), reflecting ecological degradation. Despite these stressors, mangrove populations exhibited decent growth traits, demonstrating a capacity for urban adaptation. Regulations of industrial discharge to reduce heavy metal specifically zinc contamination, coupled with targeted restoration efforts focusing on enhancing mangrove density and structural integrity, are essential to sustain these ecosystems.
Keywords:
coastal ecosystem, conservation, heavy metal toxicity, mangroves
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