The article considers the sources of dust particles formation in highways and roadside areas. The chemical composition and particle size distribution of the road dust have been analyzed. Often, the fluctuations in dust particle size distribution are significantly larger than the error of the measurement methods used. Therefore, it is necessary to consider the functions describing the particle size distribution of road dust in urban air as random ones. This method allows obtaining the characteristics of dust particle size distribution in the air and determining the average time of the fractional concentration to stay above a set level, the average number of cases of the fractional concentration to exceed the fixed level per unit time.
Copyright © 2018 Praise Worthy Prize - All rights reserved.

M. A. Marchenko, V. N. Lozhkin, N. V. Nevmerzhitskiy, On the solution of the inverse problem of modeling the hazardous effects of PM2.5 and PM10 in the vicinity of motorways, Reducing risks and eliminating the consequences of emergencies. Ensuring safety in emergency situations, Issue 2, 2015, pp. 13-23 (in Russ.).

M. V. Grafkina, A. V. Azarov, D. R. Dobrinskiy, M. M. Tikhonova, Analysis of the negative impact on the elements of the ecosystem in the process of dust emission caused by motor vehicles on road surfaces of various types, The advances of modern science. – Belgorod, 2016, 8(12), pp. 142-147 (in Russ.).

Iijima, K. Sato, K. Yano et al, Particle size and composition distribution analysis of automotive brake abrasion dusts for the evaluation of antimony sources of airborne particulate matter, Atmospheric Environment, 2007, Vol. 41, pp. 4908–4919.
http://dx.doi.org/10.1016/j.atmosenv.2007.02.005

V. V. Denisov, I. A. Denisova, V. V. Gutenev, L. N. Fesenko, Basics of engineering ecology: teaching aid, / V.V. Denisov [et al.] ed. Prof. V.V. Denisov (Rostov-on-Don: Feniks Publishers, 2013, 624p.) (in Russ.).

Goel, P. Kumar, Characterisation of nanoparticle emissions and exposure at traffic intersections through fast–response mobile and sequential measurements, Atmospheric Environment, 2015, Vol. 107, pp. 374-390.
http://dx.doi.org/10.1016/j.atmosenv.2015.02.002

D. V. Vlasov, N. S. Kasimov, N. Ye. Kosheleva, Geochemistry of road dust: (Eastern District of Moscow), / D. V. Vlasov, N. S. Kasimov, N. Ye. Kosheleva Bulletin of Moscow University. Ser. 5, Geography, 2015, № 1, pp. 23-33 (in Russ.).

Menzelitseva, N., Azarov, V., Karapuzova, N., Redhwan, A., Main Trends of Dust Conditions Normalizing at Cement Manufacturing Plants, (2015) International Review of Civil Engineering (IRECE), 6 (6), pp. 145-150.
http://dx.doi.org/10.15866/irece.v6i6.6181

E. Yu. Kozlovtseva, V. F. Loboyko, D. A. Nikolenko, Monitoring of Fine Dust Pollution of Multistory Buildings Air Environment as an Adoption Factor of Town-planning Decisions, Procedia Engineering, 2016, Vol. 150, p. 1954 – 1959.
http://dx.doi.org/10.1016/j.proeng.2016.07.197

V. N. Azarov, I. V. Tertishnikov, Ye. A. Kalyuzhina, On the assessment of fine dust concentration (PM 10 and PM 2.5) in the air, Bulletin of the Volgograd State Architectural and Construction University. Series: Construction and Architecture, 2011, № 25, pp. 402 – 406 (in Russ.).

Particle image processing program DUST1: Certificate on the state registration of software DUST 1, №2014618468 of 24.08.2014.

N. S. Barikayeva, D. A. Nikolenko, Investigation of dustiness of urban environment near highways, International Scientific Journal "Alternative Energy and Ecology", 2013, № 11 (133), pp. 75-78 (in Russ.).

D. A. Nikolenko, T. V. Solovyeva, Analysis of monitoring experience of fine dust roadside pollution in the EU countries and Russia, Engineering Journal of Don, 2015, №3, URL: ivdon.ru/ru/magazine/archive/n3y2015/3186 (in Russ.).

A. B. Strelyayeva, N. S. Barikayeva, Ye. A. Kalyuzhina, D. A. Nikolenko, Analysis of sources of air pollution with fine dust, Internet-vestnik VolgGASU. Ser.: Multi-topic, 2014, Issue 3(34). p. 11. URL: vestnik.vgasu.ru/ (in Russ.).

A. A. Sveshnikov, Applied methods of the theory of random functions: teaching aid, (SPb.: Lan Publishers, 2011, 252 p.) (in Russ.).

Health Canada and Environment Canada, National Ambient Air Quality Objectives for Particulate Matter Part 1: Science Assessment Document, 1999.

WHO. World Health Organization (WHO), Air quality guidelines for particulate matter, ozone, nitrogen dioxide and sulfur dioxide Global update 2005 Summary of risk assessment, 2005.

US EPA, Integrated Science Assessment for Particulate Matter (Final Report). United States Environmental Protection Agency (US EPA), U.S. Environmental Protection Agency, Washington, DC, 2009.

Ye. A. Luzhnikov, Medical toxicology: national guidelines (M.: GEOTAR-Media, 2012, 928 p.) (in Russ.).

Azarov, V., Evtushenko, A., Batmanov, V., Strelyaeva, A., Lupinogin, V., Aerodynamic Characteristics of Dust in the Emissions Into the Atmosphere and Working Zone of Construction Enterprises, (2016) International Review of Civil Engineering (IRECE), 7 (5), pp. 132-136.
http://dx.doi.org/10.15866/irece.v7i5.9869

Menzelintseva, N., Karapuzova, N., Mikhailovskaya, Y., Redhwan, A., Efficiency of Standards Compliance for РМ10 and РМ2,5, (2016) International Review of Civil Engineering (IRECE), 7 (6), pp. 192-195.
http://dx.doi.org/10.15866/irece.v7i6.9750