Environment Pollution Modeling on the Base of Quick Computing Models

T. I. Rusakova; O. V. Berlov; O. I. Gubin; O. Yu. Gunko; P. B. Mashykhina

doi:10.15802/stp2025/344435

Authors

T. I. Rusakova Oles Honchar Dnipro National University, Ukraine https://orcid.org/0000-0001-5526-3578
O. V. Berlov Ukrainian State University of Science and Technologies, SEI PSACEA, Ukraine https://orcid.org/0000-0002-7442-0548
O. I. Gubin Oles Honchar Dnipro National University, Ukraine https://orcid.org/0000-0001-9434-2367
O. Yu. Gunko Ukrainian State University of Science and Technologies, SEI DIIT, Ukraine https://orcid.org/0000-0001-9257-763X
P. B. Mashykhina Ukrainian State University of Science and Technologies, SEI DIIT, Ukraine https://orcid.org/0000-0003-3057-9204

DOI:

https://doi.org/10.15802/stp2025/344435

Keywords:

ground waters pollution, air pollution, landfills, emergency release, mathematical model, numerical simulation

Abstract

Purpose. Development of a fast calculation models for determining zones of ground waters and air chemical pollution during the emission of chemically hazardous substances from anthropogenic sources of pollution. To model the process of passive impurity transfer in ground waters and in atmospheric air, the G. Marchuk model is used, which takes into account the speed and direction of the flow, the intensity of the emission of chemically hazardous substances, and atmospheric diffusion (dispersion in round waters). Methodology. The process of ground waters and air pollution modeling is based on the numerical integration of the mass transfer equation (G. Marchuk model). Two numerical models were built. One numerical model was built to simulate ground waters pollution. Another numerical model was built to simulate air pollution. The construction of a numerical models of the impurity propagation process was carried out by splitting of the mass transfer equation (G. Marchuk model). Then a variable-triangular finite-difference decomposition schemes were used for numerical integration. The unknown value of the concentration of a chemically hazardous substance is carried out using explicit formulas. A set of applied programs has been developed based on the constructed numerical models. Findings. A set of applied programs has been developed based on the constructed numerical models. The results of numerical calculations are presented, showing the efficiency of the proposed numerical models. Originality. Proposed numerical models of mass transfer allow to compute quickly the areas of chemical air pollution due to the emission of toxic substances from anthropogenic sources of pollution. Practical value. Based on the proposed numerical models, a computer code has been developed. The developed models and computer code make it possible to estimate the size and intensity of environmental pollution, and can be used in solving the problem of assessing the negative impact on the ground waters and air from different sources. The results of numerical calculations show the operability of the proposed models.

References

Biliaiev, М. М., Biliaieva, V. V., Berlov, О. V., & Kozachyna, V. A. (2022). CFD-modeliuvannia v analizi efektyvnosti system zakhystu dovkillia ta pratsivnykiv na robochykh mistsiakh: monohrafiia. Dnipro: Zhurfond. (in Ukrainian)

Zhuk, H., & Predun, К. (2018). Ecological Aspects of the Biogas Usage from Disposal Sites of Solid Domestic Waste for The Energy Supplyneedsof Ukrainian Residential Areas. Ventyliatsiia, Osvitlennia ta Teplohazopostachannia, 26, 69-74. (in Ukrainian)

Zgurovskiy, M. Z., Skopetskiy, V. V., Hrusch, V. K., & Belyaev, N. N. (1997). Chislennoe modelirovanie rasprostraneniya zagryazneniya v okruzhayuschey srede. Kiev: Naukova dumka. (in Russian)

Radovenchyk, V. M., & Homelia, M. D. (2010). Tverdi vidkhody: zbir, pererobka, skladuvannia: navchalnyi posibnyk. Kyiv: Kondor. (in Ukrainian)

Satin, I. V., & Kutsyi, D. V. (2024). Greenhouse Gas Emissions From Municipal Waste Disposal Sites and Measures for Its Reduction. Scientific Reports of the National University of Life and Environmental Sciences of Ukraine, 20(3/109). DOI: https://doi.org/10.31548/dopovidi.3(109).2024.003 (in Ukrainian)

Biliaiev, M. M., & Kharytonov, M. M. (2011). Numerical Simulation of Indoor Air Pollution and Atmosphere Pollution for Regions Having Complex Topography. Air Pollution Modeling and Its Application XXI, 87-91. DOI: https://doi.org/10.1007/978-94-007-1359-8_15 (in English)

Ilić, P., Ilić, S., & Stojanović Bjelić, L. (2018). Hazard Modelling of Accidental Release Chlorine Gas Using Modern Tool-Aloha Software. Quality of Life, 9(1-2), 38-45. DOI: https://doi.org/10.7251/qol1801038i (in English)

Lacome, J.-M., Truchot, B. & Duplantier, S. (2017, Oct.). Application of an innovative risk dedicated procedure for both conventional and 3D atmospheric dispersion models evaluation. In Proceedings of 18th Interna-tional Conference on Harmonisation within Atmospheric Dispersion Modelling for Regulatory Purposes. (pp. 1-5). Bologna, Italy. (in English)

Ngusale, G. K., Oloko, M. O., Otiende, F., & Aguko, K. P. (2021). Estimation of methane and landfill gas emis-sion from an open dump site. International Journal of Environment and Waste Management, 28(3), 317-327. DOI: https://doi.org/10.1504/ijewm.2021.118368 (in English)

Trung, T. D. B., & Tri, D. Q. (2022). Application of the AERMOD Model to Evaluate the Health Benefits Due to Air Pollution from the Public Transport Sector in Ha Noi, Viet Nam. Journal of Geoscience and Environ-ment Protection, 10(3), 13-33. DOI: https://doi.org/10.4236/gep.2022.103002 (in English)

Environment Pollution Modeling on the Base of Quick Computing Models

Authors

DOI:

Keywords:

Abstract

References

Downloads

Published

How to Cite

Issue

Section

License

Information

Language

Make a Submission