Evolution of ultrafine particle size distributions following indoor episodic releases: Relative importance of coagulation, deposition and ventilation

Aerosol Science and Technology

Volumn 46, Issue 5, 2012, Pages 494-503

  Rim, Donghyun ^a   Green, Michal ^a   Wallace, Lance ^a   Persily, Andrew ^a   Choi, Jung Il ^b  

^a NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY   (United States)

^b Yonsei University   (South Korea)

Author keywords

[No Author keywords available]

Indexed keywords

COAGULATION MODELS; COAGULATION RATE; DIFFERENT SIZES; DIFFERENTIAL EFFECT; DUCTWORKS; EMPIRICAL MODEL; FRACTAL GEOMETRY; HAIRDRYERS; HAMAKER CONSTANTS; HIGH CONCENTRATION; INDOOR AEROSOL MODEL; LOSS MECHANISMS; MASS BALANCE EQUATIONS; MECHANICAL SYSTEMS; PARAMETERIZED; PARTICLE DEPOSITIONS; POWER TOOLS; SAMPLING SYSTEMS; TRACER GAS; ULTRAFINE PARTICLE; ULTRAFINE PARTICLE SIZES; VAN DER WAALS;

ATMOSPHERIC AEROSOLS; DEPOSITION; DEPOSITION RATES; GEOMECHANICS; NONLINEAR EQUATIONS; PARTICLE SIZE ANALYSIS; SIZE DISTRIBUTION; VAN DER WAALS FORCES; VENTILATION;

COAGULATION;

AEROSOL; AIR CONDITIONING; AMBIENT AIR; ARTICLE; ATMOSPHERIC DEPOSITION; CANDLE; COAGULATION; ELECTRIC STOVE; EQUIPMENT; FORCE; FRACTAL GEOMETRY; GAS STOVE; GEOMETRY; HAIR DRYER; PARTICLE SIZE; PRIORITY JOURNAL; ULTRAFINE PARTICLE; VISCOSITY;

EID: 84859187676     PISSN: 02786826     EISSN: 15217388     Source Type: Journal    
DOI: 10.1080/02786826.2011.639317     Document Type: Article

References (36)

1. Afshari, A., Matson, U., and Ekberg, L. E. (2005). Characterization of Indoor Sources of Fine and Ultrafine Particles: A Study Conducted in a Full-Scale Chamber. Indoor Air, 15;141-150.
2. Bräuner, E. V., Forchhammer, L., Møller, P., Simonsen, J., Glasius, M., Wåhlin, P., et al. (2007). Exposure to Ultrafine Particles from Ambient Air and Oxidative Stress-Induced DNA Damage, Environ. Health Perspect., 115(8):1177-1182.
3. Buonanno, G., Morawska, L., and Stabile, L., 2009. Particle Emission Factors During Cooking Activities. Atmos. Environ., 43:3235-3242.
4. Dennekamp, M., Howarth, S., Dick, C. A. J., Cherrie, J. W., Donaldson, K., and Seaton, A. (2001). Ultrafine Particles Andnitrogen Oxides Generated by Gas and Electric Cooking. Occup. Environ. Med., 58:511-516.
5. Dobbins, R. A. (2007). Hydrocarbon Nanoparticles Formed in Flames and Diesel Engines. Aerosol Sci. Technol., 41:485-496.
6. Glytsos, T., Ondracek, J., Djumbova, L., Kopanakis, I., and Lazaridis, M. (2010).Characterization of Particulate Matter Concentrations during Controlled Indoor Activities. Atmos. Environ., 44:1539-1549
7. He, C., Morawska, L., Hitchins, J., and Gilbert, D. (2004). Contribution From Indoor Sources to Particle Number and Mass Concentrations in Residential Houses. Atmos. Environ., 38:3405-3415.
8. Howard-Reed, C.,Wallace, L. A., and Emmerich, S. J. (2003). Effect of Ventilation Systems and Air Filters on Decay Rates of Particles Produced by Indoor Sources in an Occupied Townhouse. Atmos. Environ., 37(38):5295-5306.
9. Hinds, W. C. (1999). Aerosol Technology: Properties, Behavior, and Measurement ofAirborne Particles. Wiley, New York.
10. Hussein, T., Hruska, A., and Dohanyosova, P. (2009a). Deposition Rates on Smooth Surfaces and Coagulation of Aerosol Particles Inside a Test Chamber. Atmos. Environ., 43:905-914.
11. Hussein, T., Kubincová, L., Džumbová, L., Hruška, A., Dohánzosová, P., Hemerka, J., et al. (2009b). Deposition of Aerosol Particles on Rough Surfaces Inside a Test Chamber. Building Environ., 44:2056-2063.
12. Jacobson, M. Z. (2005). Fundamentals of Atmospheric Modeling (2nd ed.). Cambridge University Press, Cambridge, UK.
13. Jacobson, M. Z., and Seinfeld, J. H. (2004). Evolution of Nanoparticle Size and Mixing State Near the Point of Emission. Atmos. Environ., 38:1839-1850.
14. Klepeis, N. E., Nelson,W. C., Ott,W. R., Robinson, J. P., Tsang, A. M., Switzer, P., et al. (2001). The National Human Activity Pattern Survey (NHAPS): A resource for Assessing Exposure to Environmental Pollutants. J. Exposure Anal. Environ. Epidemiol., 11:231-252.
15. Kostoglou M., and Konstandopoulos, A. (2001). Evolution of Aggregate Size and Fractal Dimension During Brownian Coagulation. J. Aerosol Sci., 32:1399-1420.
16. Lai, A. C. K., and Nazaroff,W.W. (2000).Modeling Indoor Particle Deposition from Turbulent Flow Onto Smooth Surfaces. J. Aerosol Sci., 31:463-476.
17. Long C. M., Suh, H. H., Catalano, P. J., and Koutrakis, P. (2001). Using Timeand Size-Resolved Particulate Data to Quantify Indoor Penetration and Deposition Behavior. Environ. Sci. Technol., 35:2089-2099.
18. Matson, U. (2005). Indoor and Outdoor Concentrations of Ultrafine Particles in Some Scandinavian Rural and Urban Areas. Sci. Total Environ., 343:169-176.
19. Nazaroff, W. W. (2004). Indoor Particle Dynamics. Indoor Air, 14:175-183.
20. Nazaroff, W. W., and Cass, G. R. (1989). Mathematical Modeling of Indoor Aerosol Dynamics. Environ. Sci. Technol., 23:157-166.
21. Oberdörster, G., Stone, V., and Donaldson, K. (2007). Toxicology of Nanoparticles: A Historical Perspective. Nanotoxicology, 1:2-25.
22. Rim, D., Wallace, L., and Persily, A. (2010). Infiltration of Outdoor Ultrafine Particles into a Test House. Environ. Sci. Technol., 44:5908-5913.
23. Schmidt-Ott, A. (1988).NewApproaches to in Situ Characterization ofUltrafine Agglomerates. J Aerosol Sci. 19(5):553-557.
24. Schripp, T., Kirsch, I., and Salthammer, T. (2011). Characterization of Particle Emission from Household Electrical Appliances. Sci. Total Environ., 409(13):2534-2540.
25. Seinfeld, J.H, and Pandis, S.N. (2006).Atmospheric Chemistry and Physics-2nd Edition.Wiley, Hoboken, New Jersey.
26. Szymczak, W., Menzel, N., and Keck, L. (2007). Emission of Ultrafine Copper Particles by Universal Motors Controlled by Phase Angle. J Aerosol Sci., 38(5):520-531.
27. Stölzel, M., Breitner, S., Cyrys, J., Pitz, M., Wolke, G., Kreyling, W., et al. (2007). Daily Mortality and Particulate Matter in Different Size Classes in Erfurt, Germany. J. Expo. Sci. Environ.Epidemiol., 17(5):458-467.
28. Thatcher, T. L., Lai, A. C., Moreno-Jackson, R., Sextro, R. G., and Nazaroff, W. W. (2002). Effects of Room Furnishings and Air Speed on Particle Deposition Rates Indoors. Atmos. Environ., 36:1811-1819
29. TSI, (2007). Measuring Nanoparticle Size Distributions in Real-Time: Key Factors for Accuracy: Application Note SMPS-003. TSI Incorporated, Shoreview, MN.
30. Wallace, L. (2006). Indoor Sources of Ultrafine and Accumulation Mode Particles: Size Distributions, Size-Resolved Concentrations, and Source Strengths. Aerosol Sci. Technol., 40:348-360.
31. Wallace, L. A., Emmerich, S. J., and Howard-Reed C. (2004). Source Strengths of Ultrafine and Fine Particles Due to Cooking with a Gas Stove. Environ. Sci. Tech., 38:2304-2311.
32. Wallace, L. A., and Howard-Reed, C. H. (2002). Continuous Monitoring of Ultrafine, Fine, and Coarse Particles in a Residence for 18 Months in 1999-2000. J. Air Waste Manage. Assoc., 52(7):828-844.
33. Wallace, L. A.,Wang, F, Howard-Reed, C., and Persily, A. (2008). Contribution of Gas and Electric Stoves to Residential Ultrafine Particle Concentrations Between 2 nm and 64 nm: Size Distributions and Emission and Coagulation Rates. Environ. Sci. Tech., 42:8641-8647.
34. Whitby, E. R., and McMurry, P. H. (1997).Modal Aerosol Dynamics Modeling. Aerosol Sci. Tech., 27:673-688.
35. Xiong, C., and Friedlander, S. K. (2001). Morphological Properties of tmosphericaerosol Aggregates. Appl. Phys. Sci., 98:11851-11856.
36. Zhang, J. S., Shaw, C. Y., Nguyen-Thi, L. C., MacDonald, R. A., and Kerr, G. (1995). Field Measurements of Boundary Layer Flows in Ventilated Rooms. ASHRAE Trans., 101(Part 2):116-124.