<p>Environmental pollution stands as one of the most pressing challenges of our time, resulting in various harmful effects on ecosystems. Bioremediation emerges as a critical strategy in addressing this issue. This review is essential for enhancing our understanding of the mechanisms through which pollutants induce toxicity and the adaptive strategies that organisms employ to mitigate these contaminants. The article explores a range of mathematical models, including isotherm models, kinetic models, and thermodynamic principles, while integrating biological factors. It provides a comprehensive discussion of these mathematical frameworks and quantum principles as they relate to biological systems and processes. Additionally, it examines the molecular interactions between pollutants and organisms, framed within the context of quantum mechanical phenomena such as quantum tunneling, quantum coherence, and Cooper pair quantum entanglement. Furthermore, the article delves into the significance of pore structures, layer formation, changes in entropy, and the order of reactions, all while maintaining a biological perspective. It critically discusses the interplay of activation energy, adsorption, desorption, and the formation of boundary layers. Ultimately, the objective is to elucidate the mechanisms influenced by quantum mechanical phenomena through the application of various mathematical models, complemented by a biological viewpoint. These insights may act as a catalyst for innovative solutions to combat environmental pollution on a global scale.</p>

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Integrative bioremediation: connecting microbial processes, environmental challenges, quantum phenomenon and mathematical frameworks

  • Abhijeet Sharma,
  • Shanthy Sundaram

摘要

Environmental pollution stands as one of the most pressing challenges of our time, resulting in various harmful effects on ecosystems. Bioremediation emerges as a critical strategy in addressing this issue. This review is essential for enhancing our understanding of the mechanisms through which pollutants induce toxicity and the adaptive strategies that organisms employ to mitigate these contaminants. The article explores a range of mathematical models, including isotherm models, kinetic models, and thermodynamic principles, while integrating biological factors. It provides a comprehensive discussion of these mathematical frameworks and quantum principles as they relate to biological systems and processes. Additionally, it examines the molecular interactions between pollutants and organisms, framed within the context of quantum mechanical phenomena such as quantum tunneling, quantum coherence, and Cooper pair quantum entanglement. Furthermore, the article delves into the significance of pore structures, layer formation, changes in entropy, and the order of reactions, all while maintaining a biological perspective. It critically discusses the interplay of activation energy, adsorption, desorption, and the formation of boundary layers. Ultimately, the objective is to elucidate the mechanisms influenced by quantum mechanical phenomena through the application of various mathematical models, complemented by a biological viewpoint. These insights may act as a catalyst for innovative solutions to combat environmental pollution on a global scale.