Incheon is one of the biggest cities located in coastal region where small to big size industries, Incheon sea port, Incheon airport, etc are in operation. The air pollution dispersion from those sources has been major concerns for Incheon coastal area where air emission, dispersion and deposition have been studied using different approaches of monitoring and modeling. Essential meteorological data were acquired by field monitoring and from the published data. GTOPO30 (global digital elevation model with a horizontal grid spacing of 30”) was used as terrain data for AERMOD and USGS 30” resolution terrain data was used in A2C flow/A2C t&d model. Steady state Gaussian plume dispersion based model, i.e. AERMOD, and Lagrangian puff dispersion based model, i.e. A2Cflow/A2Ct&d models, were accomplished by introducing the local meteorological and geographical information to test the performance of models around the unsteady air flow area. AERMOD simulation results showed that the pollutants from the source are transported and dispersed around the sources similar to the average wind flow direction. There was no significant difference in pollutants dispersion regardless of land breeze or sea breeze conditions. On the other hand, the results from Lagrangian puff model showed that the puffs transport, and dispersed around the coast area followed the sea/land breeze pattern. The comparative analysis of pollutants deposition estimated by steady state Gaussian plume model and Lagrangian puff model showed that the Gaussian plume model underestimate the pollution dispersion quantity at the onshore site during day time and overestimate during late night to early morning. Hence the Lagrangian based model is recommended for estimating pollutants dispersion and deposition around the unsteady air flow region.
| Published in | American Journal of Environmental and Resource Economics (Volume 4, Issue 4) |
| DOI | 10.11648/j.ajere.20190404.16 |
| Page(s) | 152-158 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2024. Published by Science Publishing Group |
Air Dispersion Modeling, Gaussian Model, Lagrangian Model, Sea/Land Breeze, Coastal Region
| [1] | Seangkiatiyuth, K., Surapipith, V., Tantrakarnapa, K., Lothongkum, A.W. (2011). Application of the AERMOD modeling system for environmental impact assessment of NO2 emissions from a cement complex. J. of Environ. Sci. 23, 6, 931-940. |
| [2] | Arya, S. P. (1999). Air Pollution meteorology and Dispersion. Oxford University Press, pp.69-104, 269-286. |
| [3] | Srinivas, C.V., Venkatesan, R., Singh, A.B. (2007). Sensitivity of meso-scale simulations of land-sea breeze to boundary layer turbulence parameterization. Atmos. Environ. 41, 2534-2548. |
| [4] | Hsu, S.A. (1988). Coastal meteorology. Academic press, Inc. (London) LTD., pp. 141-179. |
| [5] | Kim, D., William, R.S. (2007). An online coupled meteorological and air quality modeling study of the effect of complex terrain on the regional transport and transformation of air pollutants over the Western United States. Atmos. Environ. 41, 2319-2334. |
| [6] | Karim, B., Mansour, B.F., Elouragini, S. (2007). Impact of a sea breeze event on air pollution at the Eastern Tunisian Coast. Atmos. Res. 86, 162-172. |
| [7] | Fan, S., Wang, B., Tesche, M., Engelmann, R., Althausen, A., Liu, J., Zhu, W., Fan, Q., Lim., Ta, N., Song, L., Leong, K. (2008). Meteorological condition and structures of atmospheric boundary layer in October 2004 over Pearl River Delta area. Atmos. Environ. 42, 6147-6186. |
| [8] | Peilke, R.A., Pearce, R.P. (1994). Mesoscale modeling of the atmosphere. Am. meteorol. Soc., 25, Boston, MA. |
| [9] | Yamada, T., Bunker, S. (1988). Development of a nested grid, second moment turbulence closure model and application to the 1982 ASCOT Brush Creek data simulation. Journal of Applied meteorology and Climatology 27, 562-578. |
| [10] | Yamada, T., Kao, J.C.Y., Bunker, S. (1989). Airflow and air quality simulations over the western mountainous region with a four dimensional data assimilation technique. Atmos. Environ. 23, 539-554. |
| [11] | Yamada, T. (1999). A numerical simulation of urbanization on the local climate. J. Wind Eng. Ind, Aerodyn. 81, 1-19. |
| [12] | Yamada, T. (2004). Merging CFD and atmospheric modeling capabilities to simulate airflows and dispersion in urban areas. CFD J. 13(2):47, 329-341. |
| [13] | Schutze, M., Stratmann, F. (2008). Numerical simulation of cloud droplet formation in a tank. Comput. Geosci. 34, 1034-1043. |
| [14] | Pace, C.J. (2000). DTRA urban dispersion modeling support for special security events. In: Proceedings of the 11th Joint Conference on the Application of Air Pollution meteorology with A&WMA, 9-13 January, Long Beach, CA, Am. meteorol. Soc., Boston, mA. |
| [15] | EPA (2004). AERMOD: Description of model formulation. United States Environmental Protection Agency, 8-14. |
| [16] | Jeong, J., Lee, I.H., Lee, H. (2008). Estimation of the effective region of Sea/Land breeze in west coast using numerical modeling. J. KOSAE 24, 2, 259-270. |
| [17] | Pokhrel, R., Lee, H. (2011). Estimation of the effective zone of sea/land breeze in a coastal area. APR 2, 106-115. |
| [18] | Lee, I., Lee, H. (2004). Analysis of meteorological characteristics of Sea/Land breeze in western coastal region. J. Korean Society of Urban Environ. 4, 1, 63-71. |
| [19] | Annual climatological report, Korean meteorological administration (2010). Seoul Korea. |
| [20] | Leelossy, A., Molnar Jr, F., Izsak, F., Havast, A., Lagzi, I., Meszaros, R. (2014) Dispersion modeling of air pollutants in the atmosphere: a review. Cent. Eur. J. Geosci. 6(3), 257-278. |
| [21] | Masey, N., Hamilton, S., Beverland, I.J. (2018) Development and evaluation of the Rapid Air dispersion model, including the use of geospatial surrogates to represent street canyon effects. Environmental modeling & Software, 108, 253-263. |
APA Style
Rajib Pokhrel, Heekwan Lee. (2019). Comparison of Gaussian Plume Model and Lagrangian Particle Model for the Application of Coastal Air Quality Modelling. American Journal of Environmental and Resource Economics, 4(4), 152-158. https://doi.org/10.11648/j.ajere.20190404.16
ACS Style
Rajib Pokhrel; Heekwan Lee. Comparison of Gaussian Plume Model and Lagrangian Particle Model for the Application of Coastal Air Quality Modelling. Am. J. Environ. Resour. Econ. 2019, 4(4), 152-158. doi: 10.11648/j.ajere.20190404.16
AMA Style
Rajib Pokhrel, Heekwan Lee. Comparison of Gaussian Plume Model and Lagrangian Particle Model for the Application of Coastal Air Quality Modelling. Am J Environ Resour Econ. 2019;4(4):152-158. doi: 10.11648/j.ajere.20190404.16
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Download@article{10.11648/j.ajere.20190404.16,
author = {Rajib Pokhrel and Heekwan Lee},
title = {Comparison of Gaussian Plume Model and Lagrangian Particle Model for the Application of Coastal Air Quality Modelling},
journal = {American Journal of Environmental and Resource Economics},
volume = {4},
number = {4},
pages = {152-158},
doi = {10.11648/j.ajere.20190404.16},
url = {https://doi.org/10.11648/j.ajere.20190404.16},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajere.20190404.16},
abstract = {Incheon is one of the biggest cities located in coastal region where small to big size industries, Incheon sea port, Incheon airport, etc are in operation. The air pollution dispersion from those sources has been major concerns for Incheon coastal area where air emission, dispersion and deposition have been studied using different approaches of monitoring and modeling. Essential meteorological data were acquired by field monitoring and from the published data. GTOPO30 (global digital elevation model with a horizontal grid spacing of 30”) was used as terrain data for AERMOD and USGS 30” resolution terrain data was used in A2C flow/A2C t&d model. Steady state Gaussian plume dispersion based model, i.e. AERMOD, and Lagrangian puff dispersion based model, i.e. A2Cflow/A2Ct&d models, were accomplished by introducing the local meteorological and geographical information to test the performance of models around the unsteady air flow area. AERMOD simulation results showed that the pollutants from the source are transported and dispersed around the sources similar to the average wind flow direction. There was no significant difference in pollutants dispersion regardless of land breeze or sea breeze conditions. On the other hand, the results from Lagrangian puff model showed that the puffs transport, and dispersed around the coast area followed the sea/land breeze pattern. The comparative analysis of pollutants deposition estimated by steady state Gaussian plume model and Lagrangian puff model showed that the Gaussian plume model underestimate the pollution dispersion quantity at the onshore site during day time and overestimate during late night to early morning. Hence the Lagrangian based model is recommended for estimating pollutants dispersion and deposition around the unsteady air flow region.},
year = {2019}
}
TY - JOUR T1 - Comparison of Gaussian Plume Model and Lagrangian Particle Model for the Application of Coastal Air Quality Modelling AU - Rajib Pokhrel AU - Heekwan Lee Y1 - 2019/12/04 PY - 2019 N1 - https://doi.org/10.11648/j.ajere.20190404.16 DO - 10.11648/j.ajere.20190404.16 T2 - American Journal of Environmental and Resource Economics JF - American Journal of Environmental and Resource Economics JO - American Journal of Environmental and Resource Economics SP - 152 EP - 158 PB - Science Publishing Group SN - 2578-787X UR - https://doi.org/10.11648/j.ajere.20190404.16 AB - Incheon is one of the biggest cities located in coastal region where small to big size industries, Incheon sea port, Incheon airport, etc are in operation. The air pollution dispersion from those sources has been major concerns for Incheon coastal area where air emission, dispersion and deposition have been studied using different approaches of monitoring and modeling. Essential meteorological data were acquired by field monitoring and from the published data. GTOPO30 (global digital elevation model with a horizontal grid spacing of 30”) was used as terrain data for AERMOD and USGS 30” resolution terrain data was used in A2C flow/A2C t&d model. Steady state Gaussian plume dispersion based model, i.e. AERMOD, and Lagrangian puff dispersion based model, i.e. A2Cflow/A2Ct&d models, were accomplished by introducing the local meteorological and geographical information to test the performance of models around the unsteady air flow area. AERMOD simulation results showed that the pollutants from the source are transported and dispersed around the sources similar to the average wind flow direction. There was no significant difference in pollutants dispersion regardless of land breeze or sea breeze conditions. On the other hand, the results from Lagrangian puff model showed that the puffs transport, and dispersed around the coast area followed the sea/land breeze pattern. The comparative analysis of pollutants deposition estimated by steady state Gaussian plume model and Lagrangian puff model showed that the Gaussian plume model underestimate the pollution dispersion quantity at the onshore site during day time and overestimate during late night to early morning. Hence the Lagrangian based model is recommended for estimating pollutants dispersion and deposition around the unsteady air flow region. VL - 4 IS - 4 ER -
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