Analytical techniques for understanding biofilm modeling in indoor air quality management

Q3 Mathematics

Results in Control and Optimization Pub Date : 2025-04-21 DOI:10.1016/j.rico.2025.100564

R. Vignesh Raju , N. Jeeva , M.C. Kekana , S.E. Fadugba , R. Swaminathan

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Abstract

This study presents a theoretical and mathematical framework for developing a dimensionless model to enhance the removal of volatile organic compounds (VOCs) through (botanical) biofiltration in indoor environments. Although biofiltration is a promising strategy for the control of indoor air pollution, the precise mechanism of VOC removal remains not well understood. The proposed model is formulated using nonlinear differential equations under specified boundary conditions to represent biofilm mass balance concentrations. To obtain approximate solutions, Homotopy perturbation and Akbari-Ganji analytical techniques are applied. In addition, numerical simulations are performed using MATLAB® and compared with analytical results to validate precision. The findings indicate that optimizing the biofilm thickness and reaction rates significantly enhances the removal efficiency of VOCs. Improves understanding of the behavior of biofilms through advanced mathematical analysis, contributing to the development of more effective biofiltration strategies for improved indoor air quality management.

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了解室内空气质量管理中生物膜模型的分析技术

本研究提出了一个理论和数学框架，用于开发无量纲模型，以通过（植物）生物过滤在室内环境中增强挥发性有机化合物（VOCs）的去除。虽然生物过滤是控制室内空气污染的一种很有前途的策略，但去除挥发性有机化合物的确切机制仍不清楚。该模型采用非线性微分方程在特定的边界条件下表示生物膜的质量平衡浓度。为了得到近似解，应用了同伦摄动和Akbari-Ganji解析技术。此外，利用MATLAB®进行了数值模拟，并与分析结果进行了比较，以验证精度。结果表明，优化生物膜厚度和反应速率可显著提高VOCs的去除效率。通过先进的数学分析，提高对生物膜行为的理解，有助于开发更有效的生物过滤策略，以改善室内空气质量管理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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