Effects of climate-induced salinity changes on estuarine ecosystems

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Published: 2026-04-20
DOI: https://doi.org/10.70102/4z5b5094
Keywords:
Estuarine ecosystems, Climate change, Salinity fluctuations, Biodiversity, Trophic dynamics, Ecosystem resilience, Sea-level rise

Main Article Content

Sonam Singh Bhati
Assistant Professor, Department of Computer Science & Engineering, Noida International University, Uttar Pradesh, India.
Priyamathi T
Professor, Department of Public Health, School of Allied Health Sciences, VIMS Hospital Campus, VMRF-DU, Salem, Tamil Nadu, India
Anurag Kushwaha
School of Management & Commerce, Dev Bhoomi Uttarakhand University, Uttarakhand, India.
Simran Kalra
Centre of Research Impact and Outcome, Chitkara University, Rajpura, Punjab, India.
Dr. Prakash Ranjan Behera
Assistant Professor, Department of Soil Science & Agricultural Chemistry, Institute of Agricultural Sciences, Siksha 'O' Anusandhan (Deemed to be University), Bhubaneswar, Odisha, India.
Sujayaraj Samuel Jayakumar
Assistant Professor, Department of Forensic Science, JAIN (Deemed-to-be University), Bangalore, Karnataka, India.
Dr. Wasim A. Bagwan
Krishna Institute of Science and Technology, Krishna Vishwa Vidyapeeth (Deemed to be University), Karad, Maharashtra, India.

Abstract

This paper will discuss the impacts of climate-driven salinity changes on the ecosystems and ecology of estuaries. The purpose of the paper is to analyze how the drivers of climate change, such as sea-level rise, changes in precipitation intensity, and extreme weather regimes, alter salinity regimes and eventually impact biodiversity, ecosystem processes, and socio-economic services in estuaries. The methodology will involve the qualitative analytical review, conceptual model ecosystem analysis, and interpretation of secondary data. It was assessed using synthesized information from past empirical studies, ecological data, and simulation data to evaluate biological and ecosystem processes across varying salinity levels. Simulations of the changing salinity of the ecosystem, driven by species interactions, revealed tolerance and trophic responses. The results indicate that the patterns of ecological stability and biodiversity are dramatically altered by rising salinity levels. There are some statistical predictions regarding the extent of the ecosystem's adaptation to changes in salinity. Gradual change of +5 PSU gives rise to nutrient availability of 80, reduced primary productivity of 9 g C/m2/day, and fish biomass of 300 kg/ha, which gives rise to the Human Livelihood Index of 70. With an extreme salinity (>10 PSU), the nutrient levels drop to 60%, productivity goes down to 5 g C/m2/day and the fish biomass declines to 180 kg/ha, meaning that there is extreme degradation. The decrease of nutrients to 85% and fish biomass to 280 kg/ha is caused by a freshwater surge (-5 PSU). These dynamics favor the halotolerant species and not the biodiversity that is freshwater-dependent, and also upset the trophic processes. The conclusion emerges with the reality that the salinity variable, as a result of climate change, is a decisive factor that influences the estuarine resilience, ecosystem services, and fisheries productivity. Thus, to minimize the loss of biodiversity, predictive ecological modeling and adaptive management strategies have to be implemented in the built-in monitoring of the estuarine ecosystem to alleviate a decrease in ecosystem services as well as augmentation of the long-term stability of the estuarine ecosystems under the rising climatic pressures.

Article Details

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Volume 6, Issue 1 (January-June), 2026

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Articles

How to Cite

Effects of climate-induced salinity changes on estuarine ecosystems (S. Singh Bhati, P. T, A. Kushwaha, S. Kalra, P. R. Behera, S. S. Jayakumar, & W. A. Bagwan, Trans.). (2026). International Journal of Aquatic Research and Environmental Studies, 6(1), 238-250. https://doi.org/10.70102/4z5b5094

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