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American Journal of Applied Mathematics and Statistics. 2019, 7(2), 65-74
DOI: 10.12691/AJAMS-7-2-3
Original Research

Modeling and Analysis of the Population Density Dependent Industrial Emissions of Toxic Air Pollutants and Their Control by External Species Sprayed in the Atmosphere

Shyam Sundar1, , Niranjan Swaroop1 and Ram Naresh2

1Department of Mathematics, Pranveer Singh Institute of Technology, Kanpur, India

2Department of Mathematics, School of Basic and Applied Sciences, Harcourt Butler Technical University, Kanpur, India

Pub. Date: February 03, 2019
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Cite this paper

Shyam Sundar, Niranjan Swaroop and Ram Naresh. Modeling and Analysis of the Population Density Dependent Industrial Emissions of Toxic Air Pollutants and Their Control by External Species Sprayed in the Atmosphere. American Journal of Applied Mathematics and Statistics. 2019; 7(2):65-74. doi: 10.12691/AJAMS-7-2-3

Abstract

It is well known that the human health is adversely affected by toxic air pollutants such as sulfur dioxide, nitrous oxide etc. present in the atmosphere. The removal of such pollutants from the atmosphere is, therefore, very much desirable. In this paper, a nonlinear mathematical model is proposed to study the population density dependent industrial emission of toxic air pollutants in the atmosphere and their removal by spraying liquid (water droplets) and particulate matter. In the modeling process, five variables are considered, namely; the cumulative concentration of toxic air pollutants, the density of human population affected by the toxic pollutants, the density of industrialization which is population density dependent, the number density of liquid droplets sprayed in the environment and the density of particulate matter sprayed in the environment. It is assumed that the emissions of toxic air pollutants are linearly related to the density of industrialization, the growth rate of which is directly proportional to the density of human population. It is also assumed that the growth rate of externally sprayed species in the environment is directly proportional to the concentration of toxic air pollutants in the environment. The model is analyzed using stability theory of nonlinear differential equations and numerical simulations. The model analysis shows that as the rate of spray of external species in the environment increases, the cumulative concentration of toxic air pollutants decreases. It is also found that as the rate of removal of toxic pollutants increases, the cumulative concentration of toxic air pollutants in the environment decreases. The effect of toxic air pollutants is observed to decrease the density of human population. The numerical simulation confirms analytical results.

Keywords

non linear mathematical model, pollutant, particulate matter, industrialization, stability

Copyright

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]  Dubey, B., et.al. Modeling the depletion of forestry resources by population and population pressure augmented industrialization, Applied Mathematical Modeling, 33, 3002-3014, 2009.
 
[2]  Davies, T.D., Precipitation scavenging of Sulfur dioxide in an industrial area, Atmospheric Environment, 10, 879-890, 1976.
 
[3]  Sharma, V.P., Arora, H.C., Gupta, R.K., Atmospheric pollution studies at Kanpur- suspended particulate matter, Atmospheric Environment, 17, 1307-1314, 1983.
 
[4]  Pandey, J., Agarwal, M., Khanam, N., Narayan, D., Rao, D.N., Air pollutant concentration in Varanasi, India, Atmospheric Environment, 26 (B), 91-98, 1992.
 
[5]  Pillai, A., Naik, M.S., Momin, G., Rao, P., Ali, K., Rodhe, H., Granet, L., Studies of wet deposition and dust fall at Pune, India, Water, Air, & Soil Pollution, 130 (1-4), 475-480, 2001.
 
[6]  Chang, T.Y., Rain and snow scavenging of HNO3 vapour in the atmosphere, Atmospheric Environment, 18, 191-197, 1984.
 
[7]  Chen, W.H., Atmospheric ammonia scavenging mechanisms round a liquid droplet in convective flow, Atmospheric Environment, 38 (8), 1107-1116, 2004.
 
[8]  Fisher, B.E.A., The transport and removal of sulfur dioxide in a rain system, Atmospheric Environment, 16, 775-783, 1982.
 
[9]  Goncalves, F.L.T., Ramos, A.M, Freitas, S, Silva Dias, M.A., Massambani, O., In cloud and below cloud numerical simulation of scavenging processes at Serra Do Mar Region S E Brazil, Atmospheric Environment, 36, 5245-5255, 2002.
 
[10]  Hales, J.M., Fundamentals of the theory of gas scavenging by rain, Atmospheric Environment, 6, 635- 650, 1972.
 
[11]  Hales, J.M., Wet removal of sulphur compounds from the atmosphere, Atmospheric Environment, 12, 389-400, 1978.
 
[12]  Koelliker, Y., Totten, L.A., Gigliotti, C.L., Offenberg, H, Reinfelder, J.R., Zhuang, Y, Eisenreich, S.J., Atmospheric wet deposition of total phosphorus in New Jersey, Water, Air, & Soil Pollution, 154 (1-4), 139-150, 2004.
 
[13]  Kumar, S., An Eulerian model for scavenging of pollutants by rain drops, Atmospheric Environment, 19, 769-778, 1985.
 
[14]  Levine, S.Z., Schwartz, S.E., In-cloud and below-cloud scavenging of HNO3vapors, Atmospheric Environment, 16, 1725-1734, 1982.
 
[15]  Pandis, S.N., Seinfeld, J.H., On the interaction between equilibration processes and wet or dry deposition, Atmospheric Environment, 24(A), 2313-2327, 1990.
 
[16]  Rao, P.S.P., Khemani, L.T., Momin, G.A., Safari, P.D., Pillai, A.G., Measurements on wet and dry deposition at an urban location in India, Atmospheric Environment, 26(B), 73-78, 1992.
 
[17]  Bariie L.A., An improved model of reversible SO2 washout by rain, Atmospheric Environment, 12, 407- 412, 1978.
 
[18]  Sundar, S., Sharma, R.K., Naresh, R., Modeling the role of cloud density on the removal of gaseous pollutants and particulate matters from the atmosphere, Application and Applied Mathematics: An International Journal, 8 (2), 416-435, 2013.
 
[19]  Shukla, J.B., Misra, A.K., Sundar, S, Naresh, R., Effect of rain on removal of a gaseous pollutant and two different particulate matters from the atmosphere of a city, Mathematical and Computer Modeling, 48, 832- 844, 2008.
 
[20]  Shukla, J.B., Sundar, S., Misra, A.K., Naresh, R., Modeling the removal of gaseous pollutants and particulate matters from the atmosphere of a city by rain: Effect of cloud density, Environmental Model Assessment, 13, 255-263, 2008.
 
[21]  Naresh, R., Sundar, S., Mathematical modeling and analysis of the removal of gaseous pollutants by precipitation using general nonlinear interaction, International Journal of Applied Mathematics and Computation, 2(2), 45- 56, 2010.