1. Y. Sun, Y. He, Y. Kuang, W. Xu, S. Song, N. Ma, J. Tao, P. Cheng, C. Wu, H. Su, Y. Cheng, C. Xie, C. Chen, L. Lei,
    Y. Qiu, P. Fu, P. Croteau, D.R. Worsnop, Chemical differences between PM1 and PM2.5 in highly polluted environment and implications in air pollution studies, Geophys. Res. Lett., 47 (2020) e2019GL086288, doi:10.1029/2019GL086288.
  2. Q. Zhang, J. Jimenez, M.R. Canagaratna, I.M. Ulbrich, N.L. Ng, D.R. Worsnop, Y. Sun, Understanding atmospheric organic aerosols via factor analysis of aerosol mass spectrometry: a review, Anal. Bioanal. Chem., 401 (2011) 3045–3067.
  3. G.J. Zheng, F.K. Duan, H. Su, Y.L. Ma, Y. Cheng, B. Zheng, Q. Zhang, T. Huang, T. Kimoto, D. Chang, U. Pöschl,
    Y.F. Cheng, K.B He, Exploring the severe winter haze in Beijing: the impact of synoptic weather, regional transport and heterogeneous reactions, Atmos. Chem. Phys., 15 (2015) 2969–2983.
  4. Y.J. Li, Y. Sun, Q. Zhang, X. Li, M. Li, Z. Zhou, C.K. Chan, Real-time chemical characterization of atmospheric particulate matter in China: a review, Atmos. Environ., 158 (2017) 270–304.
  5. M.L. Bosko, D. Varrica, G. Dongarrà, Case study: inorganic pollutants associated with particulate matter from an area near a petrochemical plant, Environ. Res., 99 (2005) 18–30.
  6. M.A. Alghamdi, Characteristics and risk assessment of heavy metals in airborne PM10 from a residential area of northern Jeddah city, Saudi Arabia, Pol. J. Environ. Stud., 25 (2016) 939–949.
  7. J. Lin, D. Pan, S.J. Davis, Q. Zhang, Q.K. He, C. Wang, D.G. Streets, D.J. Wuebbles, D. Guan, China’s international trade and air pollution in the United States, Proc. Natl. Acad. Sci. U.S.A., 111 (2014) 1736–1741.
  8. Y.-F. Xing, Y.-H. Xu, M.-H. Shi, Y.-X. Lian, The impact of PM2.5 on the human respiratory system, J. Thorac. Dis., 8 (2016) 69–74.
  9. Z. Guo, Q. Guo, S. Chen, B. Zhu, Y. Zhang, J. Yu, Z. Guo, Study on pollution behavior and sulfate formation during the typical haze event in Nanjing with water soluble inorganic ions and sulfur isotopes, Atmos. Res., 217 (2019) 198–207.
  10. A. De Marco, C. Proietti, A. Anav, L. Ciancarella, I. D’Elia, S. Fares, M.F. Fornasier, L. Fusaro, M. Gualtieri,
    F. Manes, A. Marchetto, M. Mircea, E. Paoletti, A. Piersanti, M. Rogora, L. Salvati, E. Salvatori, A. Screpanti,
    G. Vialetto, M. Vitale, C. Leonardi, Impacts of air pollution on human and ecosystem health, and implications for the National Emission Ceilings Directive: insights from Italy, Environ. Int., 125 (2019) 320–333.
  11. M. Zacarias, D. Pizzol, H. de Miranda, A.C. Colangelo, N. Veronese, L. Smith, Schistosomal appendicitis: case series and systematic literature review, PLoS Negl. Trop. Dis., 15 (2021) e0009478, doi:10.1371/journal.pntd.0009478.
  12. A. Przybysz, R. Popek, M. Stankiewicz-Kosyl, Ch.Y. Zhu, M. Małecka-Przybysz, T. Maulidyawati, K. Mikowska,
    D. Deluga, K. Griżuk, J. Sokalski-Wieczorek, K. Wolszczak, M. Wińska-Krysiak, Where trees cannot grow – particulate matter accumulation by urban meadows, Sci. Total Environ., 785 (2021) 147310, doi:10.1016/j.scitotenv.2021.147310.
  13. Y. Li, S. Wang, Q. Chen, Potential of thirteen urban greening plants to capture particulate matter on leaf surfaces across three levels of ambient atmospheric pollution, Int. J. Environ. Res. Public Health, 16 (2019) 402, doi: 10.3390/ijerph16030402.
  14. A. Łukowski, R. Popek, P. Karolewski, Particulate matter on foliage of Betula pendula, Quercus robur, and Tilia cordata: deposition and ecophysiology, Environ. Sci. Pollut. Res., 27 (2020) 10296–10307.
  15. R. Popek, A. Łukowski, M. Grabowski, Influence of particulate matter accumulation on photosynthetic apparatus of Physocarpus opulifolius and Sorbaria sorbifolia, Pol. J. Environ. Stud., 27 (2018) 2391–2396.
  16. T.A.M. Pugh, A. Robert MacKenzie, J. Duncan Whyatt, C. Nicholas Hewitt, Effectiveness of green infrastructure for improvement of air quality in urban street canyons, Environ. Sci. Technol., 46 (2012) 7692–7699.
  17. D. Liang, C. Ma, Y.-q. Wang, Y.-j. Wang, Z. Chen-xi, Quantifying PM2.5 capture capability of greening trees based on leaf factors analysing, Environ. Sci. Pollut. Res., 23 (2016) 21176–21186.
  18. T. Kroeger, R.I. McDonald, T. Boucher, P. Zhang, L. Wang, Where the people are: current trends and future potential targeted investments in urban trees for PM10 and temperature mitigation in 27 U.S. cities, Landscape Urban Plann., 177 (2018) 227–240.
  19. J. Yang, J. McBride, J. Zhou, Z. Sun, The urban forest in Beijing and its role in air pollution reduction, Urban For. Urban Greening, 3 (2005) 65–78.
  20. Y. Xu, W. Xu, L. Mo, M.R. Heal, X. Xu, X. Yu, Quantifying particulate matter accumulated on leaves by 17 species of urban trees in Beijing, China, Environ. Sci. Pollut. Res., 25 (2018) 12545–12556.
  21. Z. Chiam, X.P. Song, L.H. Ran, H.T.W. Tan, Particulate matter mitigation via plants: understanding complex relationships with leaf traits, Sci. Total Environ., 688 (2019) 398–408.
  22. R. Popek, H. Gawrońska, M. Wrochna, S.W. Gawroński, A. Sæbø, Particulate matter on foliage of 13 woody species: deposition on surfaces and phytostabilisation in waxes—a 3 year study, Int. J. Phytorem., 15 (2013) 245–256.
  23. R.J. Leonard, C. McArthur, D.F. Hochuli, Particulate matter deposition on roadside plants and the importance of leaf trait combinations, Urban For. Urban Greening, 20 (2016) 249–253.
  24. R. Mitchell, B.A. Maher, R. Kinnersley, Rates of particulate pollution deposition onto leaf surfaces: temporal and interspecies magnetic analyses, Environ. Pollut., 158 (2010) 1472–1478.
  25. M. Tomašević, Z. Vukmirović, S. Rajšić, M. Tasić, B. Stevanović, Characterization of trace metal particles deposited on some deciduous tree leaves in an urban area, Chemosphere, 61 (2005) 753–760.
  26. X. Xu, J. Xia, Y. Gao, W. Zheng, Additional focus on particulate matter wash-off events from leaves is required: a review of studies of urban plants used to reduce airborne particulate matter pollution, Urban For. Urban Greening, 48 (2020) 126559, doi: 10.1016/j.ufug.2019.126559.
  27. H. Wang, H. Shi, Y. Wang, Effects of weather, time, and pollution level on the amount of particulate matter deposited on leaves of Ligustrum lucidum, Sci. World J., 2015 (2015) 935942, doi: 10.1155/2015/935942.
  28. B. Czernecki, B.M. Półrolniczak, L. Kolendowicz, M. Marosz, S. Kendzierski, N. Pilguj, Influence of the atmospheric conditions on PM10 concentrations in Poznań, Poland, J. Atmos. Chem., 74 (2017) 115–139.
  29. X. Xu, X. Yu, L. Bao, A.R. Desai, Size distribution of particulate matter in runoff from different leaf surfaces during controlled rainfall processes, Environ. Pollut., 255 (2019) 113234, doi: 10.1016/j.envpol.2019.113234.
  30. V. Viippola, V. Yli-Pelkonen, L. Järvi, M. Kulmala, H. Setälä, Effects of forests on particle number concentrations in nearroad environments across three geographic regions, Environ. Pollut., 266 (2020) 115294, doi:10.1016/j.envpol.2020.115294.
  31. T. Schaubroeck, G. Deckmyn, J. Neirynck, J. Staelens, S. Adriaenssens, J. Dewulf, B. Muys, K. Verheyen, Multilayered modeling of particulate matter removal by a growing forest over time, from plant surface deposition to wash-off via rainfall, Environ. Sci. Technol., 48 (2014) 10785–10794.
  32. U. Weerakkody, J.W. Dover, P. Mitchell, K. Reiling, Evaluating the impact of individual leaf traits on atmospheric particulate matter accumulation using natural and synthetic leaves, Urban For. Urban Greening, 30 (2018) 98–107.
  33. G. Tian, Z. Qiao, X. Xu, Characteristics of particulate matter (PM10) and its relationship with meteorological factors during 2001–2012 in Beijing, Environ. Pollut., 192 (2014) 266–274.
  34. C. Xie, L. Kan, J. Guo, S. Jin, Z. Li, D. Chen, X. Li, S. Che, A dynamic processes study of PM retention by trees under different wind conditions, Environ. Pollut., 233 (2018) 315–322.
  35. L.C. Blanco Becerra, A.I. Gáfaro Rojas, N.Y. Rojas Roa, Influence of precipitation scavenging on the PM2.5/PM10 ratio at the Kennedy locality of Bogotá, Colombia, Rev. Fac. Ing. Univ. Antioquia, 76 (2015) 58–62.
  36. L. Liu, D. Guan, M.R. Peart, G. Wang, H. Zhang, Z. Li, The dust retention capacities of urban vegetation—a case study of Guangzhou, South China, Environ. Sci. Pollut. Res. Int., 20 (2013) 6601–6610.
  37. R. Popek, A. Haynes, A. Przybysz, S.A. Robinson, How much does weather matter? Effects of rain and wind on PM accumulation by four species of Australian native trees, Atmosphere, 10 (2019) 633, doi:10.3390/atmos10100633.
  38. X. Xu, Z. Zhang, L. Bao, L. Mo, X. Yu, D. Fan, X. Lun, Influence of rainfall duration and intensity on particulate matter removal from plant leaves, Sci. Total Environ., 609 (2017) 11–16.
  39. A. Przybysz, M. Wińska-Krysiak, M. Małecka-Przybysz, M. Stankiewicz-Kosyl, M. Skwara, A. Kłos, S. Kowalczyk, K. Jarocka, P. Sikorski, Urban wastelands: on the frontline between air pollution sources and residential areas, Sci. Total Environ., 721 (2020) 137695, doi: 10.1016/j.scitotenv.2020.137695.
  40. H. Wang, H. Shi, Particle retention capacity, efficiency, and mechanism of selected plant species: implications for urban planting for improving urban air quality, Plants, 10 (2021) 2109, doi: 10.3390/plants10102109.
  41. A. Przybysz, A. Sæbø, H.M. Hanslin, S.W. Gawroński, Accumulation of particulate matter and trace elements on vegetation as affected by pollution level, rainfall and the passage of time, Sci. Total Environ., 481 (2014) 360–369.
  42. U. Weerakkody, J.W. Dover, P. Mitchell, K. Reiling, Quantification of the traffic-generated particulate matter capture by plant species in a living wall and evaluation of the important leaf characteristics, Sci. Total Environ., 635 (2018) 1012–1024.
  43. G. Yan, J. Liu, L. Zhu, J. Zhai, C. Ling, Effectiveness of wetland plants as biofilters for inhalable particles in an urban park, Geomorphology, 306 (2018) 28–39.
  44. A. Sæbø, R. Popek, B. Nawrot, H.M. Hanslin, H. Gawronska, S.W. Gawronski, Plant species differences in particulate matter accumulation on leaf surfaces, Sci. Total Environ., 427–428 (2012) 347–354.
  45. K. Dzierżanowski, R. Popek, H. Gawrońska, A. Sæbø, S.W. Gawroński, Deposition of particulate matter of different size fractions on leaf surfaces and in waxes of urban forest species, Int. J. Phytorem., 13 (2011) 1037–1046.
  46. L. Chen, C. Liu, R. Zou, M. Yang, Z. Zhang, Experimental examination of effectiveness of vegetation as bio-filter of particulate matters in the urban environment, Environ. Pollut., 208 (2016) 198–208.
  47. U. Weerakkody, J.W. Dover, P. Mitchell, K. Reiling, Particulate matter pollution capture by leaves of seventeen living wall species with special reference to rail-traffic at a metropolitan station, Urban For. Urban Greening, 27 (2017) 173–186.
  48. T. Nguyen, X. Yu, Z. Zhang, M. Liu, X. Liu, Relationship between types of urban forest and PM2.5 capture at three growth stages of leaves, J. Environ. Sci., 27 (2015) 33–41.
  49. A. Haynes, R. Popek, M. Boles, C. Paton-Walsh, S.A. Robinson, Roadside moss turfs in South East Australia capture more particulate matter along an urban gradient than a common native tree species, Atmosphere, 10 (2019) 224, doi: 10.3390/atmos10040224.
  50. W. Zhang, Z. Zhang, H. Meng, T. Zhang, How does leaf surface micromorphology of different trees impact their ability to capture particulate matter?, Forests, 9 (2018) 681, doi: 10.3390/f9110681.
  51. A. Pal, K. Kulshreshtha, K.J. Ahmad, H.M. Behl, Do leaf surface characters play a role in plant resistance to auto-exhaust pollution?, Flora, 197 (2002) 47–55.
  52. L. Mo, Z. Ma, Y. Xu, F. Sun, X. Lun, X. Liu, J. Chen, X. Yu, Assessing the capacity of plant species to accumulate particulate matter in Beijing, China, PLoS One, 10 (2015) e0140664, doi: 10.1371/journal.pone.0140664.
  53. C. Neinhuis, W. Barthlott, Seasonal changes of leaf surface contamination in beech, oak, and ginkgo in relation to leaf micromorphology and wettability, New Phytol., 138 (1998) 91–98.
  54. K. Paul Beckett, P.H. Freer-Smith, G. Taylor, Particulate pollution capture by urban trees: effect of species and windspeed, Global Change Biol., 6 (2000) 995–1003.
  55. H. Wang, H. Shi, Y. Li, Y. Yu, J. Zhang, Seasonal variations in leaf capturing of particulate matter, surface wettability and micromorphology in urban tree species, Front. Environ. Sci. Eng., 7 (2013) 579–588.
  56. L. Chen, C. Liu, L. Zhang, R. Zou, Z. Zhang, Variation in tree species ability to capture and retain airborne fine particulate matter (PM2.5), Sci. Rep., 7 (2017) 3206, doi: 10.1038/s41598-017-03360-1.