DIFFERENTIAL EQUATIONS IN DETECTING ENVIRONMENTAL PROBLEMS AND POLLUTION
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Abstract
Environmental pollution represents one of the most critical challenges facing modern society, requiring sophisticated mathematical tools for accurate prediction and analysis. The research synthesizes findings from multiple sources to establish the theoretical framework and practical applications of differential equation models in environmental monitoring. Results indicate that differential equations provide robust mathematical foundations for predicting pollution trajectories, assessing contamination levels, and developing effective mitigation strategies. The analysis reveals significant correlations between mathematical modeling accuracy and real-world environmental conditions, though model limitations related to parameter estimation and boundary conditions require careful consideration.
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References
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