• Title of article

    Deposition rates on smooth surfaces and coagulation of aerosol particles inside a test chamber

  • Author/Authors

    Hussein، نويسنده , , Tareq and Hru?ka، نويسنده , , Ale? and Doh?nyosov?، نويسنده , , Pavla and D?umbov?، نويسنده , , Lucie and Hemerka، نويسنده , , Ji?? and Kulmala، نويسنده , , Markku and Smol?k، نويسنده , , Ji??، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2009
  • Pages
    10
  • From page
    905
  • To page
    914
  • Abstract
    Because aerosol particle deposition is an important factor in indoor air quality, many empirical and theoretical studies have attempted to understand the process. In this study, we estimated the deposition rate of aerosol particles on smooth aluminum surfaces inside a test chamber. We investigated the influence of turbulent intensity due to ventilation and fan operation. We also investigated two important processes in particle deposition: turbophoresis, which is significant for micron particles, and coagulation, which is relevant to ultrafine particles (UFP diameter <0.1 μm) at high particle concentrations. Our analysis included semi-empirical estimates of the deposition rates that were compared to available deposition models and verified with simulations of an aerosol dynamics model. In agreement with previous studies, this study found that induced turbulent intensity greatly enhanced deposition rates of fine particles (FP diameter <1 μm). The deposition rate of FP was proportional to the ventilation rate, and it increased monotonically with fan speed. With our setup, turbophoresis was very important for coarse particles larger than 5 μm. The coagulation of aerosol particles was insignificant when the particle concentration was less than 104 cm−3 during fan operation. The model simulation results verified that the aerosol dynamics module incorporated in our Multi-Compartment and Size-Resolved Indoor Aerosol Model (MC-SIAM) was valid. The behavior of aerosol particles inside our chamber was similar to that found in real-life conditions with the same ventilation rates (0.018–0.39 h−1) and similar air mixing modes. Therefore, our findings provide insight into indoor particle behavior.
  • Keywords
    Turbophoresis , Turbulent intensity , Deposition Rate , MODELING , Coagulation
  • Journal title
    Atmospheric Environment
  • Serial Year
    2009
  • Journal title
    Atmospheric Environment
  • Record number

    2234553