Articles | Volume 10, issue 23
Atmos. Chem. Phys., 10, 11337–11357, 2010

Special issue: Measurement and modeling of aerosol emissions from biomass...

Atmos. Chem. Phys., 10, 11337–11357, 2010

  01 Dec 2010

01 Dec 2010

Impact of biomass burning on ocean water quality in Southeast Asia through atmospheric deposition: eutrophication modeling

P. Sundarambal1,2, P. Tkalich1, and R. Balasubramanian3,4 P. Sundarambal et al.
  • 1Tropical Marine Science Institute, 14 Kent Ridge Road, National University of Singapore, 119223, Singapore
  • 2Department of Chemical and Biomolecular Engineering, National University of Singapore, 117576, Singapore
  • 3Division of Environmental Science and Engineering, National University of Singapore, 117576, Singapore
  • 4Singapore Delft Water Alliance, National University of Singapore, Engineering Drive 1, 117576, Singapore

Abstract. Atmospheric deposition of nutrients (N and P species) can intensify anthropogenic eutrophication of coastal waters. It was found that the atmospheric wet and dry depositions of nutrients was remarkable in the Southeast Asian region during the course of smoke haze events, as discussed in a companion paper on field observations (Sundarambal et al., 2010b). The importance of atmospheric deposition of nutrients in terms of their biological responses in the coastal waters of the Singapore region was investigated during hazy days in relation to non-hazy days. The influence of atmospherically-derived, bio-available nutrients (both inorganic and organic nitrogen and phosphorus species) on the coastal water quality between hazy and non-hazy days was studied. A numerical modeling approach was employed to provide qualitative and quantitative understanding of the relative importance of atmospheric and ocean nutrient fluxes in this region. A 3-D eutrophication model, NEUTRO, was used with enhanced features to simulate the spatial distribution and temporal variations of nutrients, plankton and dissolved oxygen due to atmospheric nutrient loadings. The percentage increase of the concentration of coastal water nutrients relative to the baseline due to atmospheric deposition was estimated between hazy and non-hazy days. Model computations showed that atmospheric deposition fluxes of nutrients might account for up to 17 to 88% and 4 to 24% of total mass of nitrite + nitrate-nitrogen in the water column, during hazy days and non-hazy days, respectively. The results obtained from the modeling study could be used for a better understanding of the energy flow in the coastal zone system, exploring various possible scenarios concerning the atmospheric deposition of nutrients onto the coastal zone and studying their impacts on water quality.

Final-revised paper