Abstract
Outdoor particles are a major contributor to indoor particles which influence the indoor air quality. The outdoor particle concentration also affects the outdoor air quality but the real outdoor particle concentration around buildings may differ from monitored concentrations at monitoring sites. One main factor is the effect of vegetation, especially trees. Numerical simulations were used to investigate the effects of trees on particle concentration distributions around target buildings. The drift flux model was combined with the Reynolds-Averaged Navier-Stokes (RANS) model to model the particle distribution and the airflow. Thirteen cases were analyzed to compare the effects of tree type, tree-building distance and tree canopy-canopy distance on the outdoor particle concentration distribution. The results show that cypress trees reduce the outdoor particle concentration more than pine trees, that shorter tree-building distances (TBD) reduce the particle concentration more than longer tree-building distances, and that a zero tree canopy-canopy distance (CCD) reduces the particle concentration more than CCD=2 m. These results provide guidelines for determining the most effective configuration for trees to reduce outdoor particle concentrations near buildings.
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References
Abt E, Suh HH, Catalano P, Koutrakis P (2000). Relative contribution of outdoor and indoor particle sources to indoor concentrations. Environmental Science Technology, 34: 3579–3587.
Ahmadi G, Li A (2000). Computer simulation of particle transport and deposition near a small isolated building. Journal of Wind Engineering and Industrial Aerodynamics, 84: 23–46.
Barratt R (2001). Atmospheric dispersion modelling: An introduction to practical applications. London: Earthscan Publications.
Beckett KP, Freer-Smith PH, Taylor G (2000). Effective tree species for local air quality management. Journal of Arboriculture, 26: 12–19.
Blocken B, Tominaga Y, Stathopoulos T (2013). CFD simulation of micro-scale pollutant dispersion in the built environment. Building and Environment, 64: 225–230.
Chen C. Zhao B (2011). RReview of relationship between indoor and outdoor particles: I/O ratio, infiltration factor and penetration factor. Atmospheric Environment, 5: 275–288.
Dzierzanowski K, Gawronski SW (2011). Use of trees for reducing particulate matter pollution in air. Challenges of Modern Technology, 2: 69–73.
Dzierzanowski K, Popek R, Gawronska H, Sebu A, Gawronski SW (2011). Deposition of particulate matter of different size fractions on leaf surfaces and in waxes of urban forest species. International Journal of Phytoremediation, 13: 1037–1046.
Feng N, Ma J, Lin B, Zhu Y (2009). Impact of landscape on wind environment in residential area. Journal of Central South University of Technology, 16: 80–83.
Freer-Smith PH, Beckett KP, Taylor G (2005). Deposition velocities to Sorbus aria, Acer campestre, Populus deltoids × trichocarpa ‘Beaupré’, Pinus nigra and × Cupressocyparis leylandii for coarse, fine and ultra-fine particles in the urban environment. Environmental Pollution, 133: 157–167
Gromke C (2011). A vegetation modeling concept for building and environmental aerodynamics wind tunnel tests and its application in pollutant dispersion studies. Environmental Pollution, 159: 2094–2099.
Kessler R (2013). Green walls could cut street-canyon air pollution. Environmental Health Perspectives, 121: A14.
Klepeis NE, Nelson WC, Ott WR, Robinson JP, Tsang AM, Switzer P, Behar JV, Hern SC, Engelmann WH (2001). The National Human Activity Pattern Survey (NHAPS): A resource for assessing exposure to environmental pollutants. Journal of Exposure Analysis and Environmental Epidemiology, 11: 231–252.
Kopperud RJ, Ferro AR, Hildemann LM (2004). Outdoor versus indoor contributions to indoor particulate matter (PM) determined by mass balance methods. Journal of the Air Waste Management Association, 54: 1188–1196.
Lateb M, Masson C, Stathopoulos T, Bédard C (2010). Numerical simulation of pollutant dispersion around a building complex. Building and Environment, 45: 1788–1798.
Lee RL (1998). Lagrangian stochastic particle model simulations of turbulent dispersion around buildings. Atmospheric Environment, 32: 665–672.
Lee SC, Lam S, Kin FH (2001). Characterization of VOCs, ozone, and PM10 emissions from office equipment in an environmental chamber. Building and Environment, 36: 837–842.
Leung KK, Liu CH, Wong CC, Lo JC, Ng GC (2012). On the study of ventilation and pollutant removal over idealized two-dimensional urban street canyons. Building Simulation, 5: 359–369.
Leuzzi G, Monti P (1998). Particle trajectory simulation of dispersion around a building. Atmospheric Environment, 32: 203–214.
Letz R, Ryan PB, Spengler JD (1984). Estimated distributions of personal exposure to respirable particles. Environmental Monitoring and Assessment, 4: 351–359.
Li L, Li XF, Lin BR, Zhu YX (2006). Improved k-ɛ two-equation turbulence model for canopy flow. Atmospheric Environment, 40: 762–770.
Lin B, Li X, Zhu Y, Qin Y (2008). Numerical simulation studies of the different vegetation patterns’ effects on outdoor pedestrian thermal comfort. Journal of Wind Engineering and Industrial Aerodynamics, 96: 1707–1718.
Liu X, Niu J, Kwok KC (2013). Evaluation of RANS turbulence models for simulating wind-induced mean pressures and dispersions around a complex-shaped high-rise building. Building Simulation, 6: 151–164.
McDonald AG, Bealey WJ, Fowler D, Dragosits U, Skiba U, Smith RI, Donovan RG, Brett HE, Hewitt CN, Nemitz E (2007). Quantifying the effect of urban tree planting on concentrations and depositions of PM10 in two UK conurbations. Atmospheric Environment, 41: 8455–8467.
Mfula AM, Kukadia V, Griffiths RF, Hall DJ (2005). Wind tunnel modelling of urban building exposure to outdoor pollution. Atmospheric Environment, 39: 2737–2745.
Nawrot B, Dzierżanowski K, Gawroński SW (2011). Accumulation of particulate matter, PAHs and heavy metals in canopy of small-leaved lime. Environmental Protection and Natural Resources, 49: 52–60.
Popek R, Gawrońska H, Wrochna M, Gawroński SW, Sæbø A (2013). Particulate matter on foliage of 13 woody species: Deposition on surfaces and phytostabilisation in waxes-A 3-year study. International Journal of Phytoremediation, 15: 245–256.
Ries K, Eichhorn J (2001). Simulation of effects of vegetation on the dispersion of pollutants in street canyons. Meteorologische Zeitschrift, 10: 229–233.
Roache PJ (1994). Perspective: A method for uniform reporting of grid refinement studies. Journal of Fluids Engineering, 116: 405–413.
Sæbø A, Popek R, Nawrot B, Hanslin HM, Gawronska H, Gawronski SW (2012). Plant species differences in particulate matter accumulation on leaf surfaces. Science of the Total Environment, 427: 347–354.
Schatzmann M, Britter R (2011). Quality assurance and improvement of micro-scale meteorological models. International Journal of Environment and Pollution, 44: 139–146.
Spalding B (2009). PHOENICS. CHAM TR/100.
Sun Y, Zhuang G, Wang Y, Han L, Guo J, Dan M, Zhang W, Wang Z, Hao Z (2004). The air-borne particulate pollution in Beijing-Concentration, composition, distribution and sources. Atmospheric Environment, 38: 5991–6004.
Terzaghi E, Wild E, Zacchello G, Cerabolini BEL, Jones KC, Di Guardo A (2013). Forest filter effect: Role of leaves in capturing/releasing air particulate matter and its associated PAHs. Atmospheric Environment, 74: 378–384.
Tominaga Y, Mochida A, Yoshie R, Kataoka H, Nozu T, Yoshikawa M, Shirasawa T (2008). AIJ guidelines for practical applications of CFD to pedestrian wind environment around buildings. Journal of Wind Engineering and Industrial Aerodynamics, 96: 1749–1761.
Turpin BJ, Weisel CP, Morandi M, Colome S, Stock T, Eisenreich S, Buckley B, (2007). Relationships of indoor, outdoor, and personal air (RIOPA): Part II. Analyses of concentrations of particulate matter species. Research Report, Health Effects Institute 130.
van Donkelaar A, Martin RV, Brauer M, Kahn R, Levy R, Verduzco C, Villeneuve PJ (2010). Global estimates of ambient fine particulate matter concentrations from satellite-based aerosol optical depth: Development and application. Environmental Health Perspectives, 118: 847–855.
Xu Z (2012). Air Clean Technology. Beijing: Science Press. (In Chinese)
Zhang YW, Gu ZL, Lee SC, Fu TM, Ho KF (2011). Numerical simulation and in situ investigation of fine particle dispersion in an actual deep street canyon in Hong Kong. Indoor and Built Environment, 20: 206–216.
Zhao B, Chen C, Tan Z (2009). Modeling of ultrafine particle dispersion in indoor environments with an improved drift flux model. Journal of Aerosol Science, 40: 29–43.
Zhao B, Yang C, Yang X, Liu S (2008). Particle dispersion and deposition in ventilated rooms: Testing and evaluation of different Eulerian and Lagrangian models. Building and Environment, 43: 388–397.
Zhou B, Zhao B (2011). Test of a generalized drift flux model for simulating indoor particle dispersion. In: Proceedings of ISHVAC, Shanghai, China.
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Ji, W., Zhao, B. Numerical study of the effects of trees on outdoor particle concentration distributions. Build. Simul. 7, 417–427 (2014). https://doi.org/10.1007/s12273-014-0180-9
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DOI: https://doi.org/10.1007/s12273-014-0180-9