Journal of Geoscience and Environment Protection
Vol.03 No.06(2015), Article ID:59038,6 pages
10.4236/gep.2015.36013

Assessing the Impact of Using Different Land Cover Classification in Regional Modeling Studies for the Manaus Area, Brazil

Sameh Adib Abou Rafee1*, Ana Beatriz Kawashima1, Marcos Vinícius Bueno de Morais1, Viviana Urbina3, Leila Droprinchinski Martins2, Jorge Alberto Martins¹

1Department of Physics, Federal University of Technology-Parana, Londrina, Brazil

2Department of Chemistry, Federal University of Technology-Parana, Londrina, Brazil

3Department of Atmospheric Sciences, University of São Paulo, São Paulo, Brazil

Email: *samehh_@hotmail.com

Received 11 June 2015; accepted 21 August 2015; published 25 August 2015

ABSTRACT

Land cover classification is one of the main components of the modern weather research and forecasting models, which can influence the meteorological variable, and in turn the concentration of air pollutants. In this study the impact of using two traditional land use classifications, the United States Geological Survey (USGS) and the Moderate-resolution Imaging Spectroradiometer (MODIS), were evaluated. The Weather Research and Forecasting model (WRF, version 3.2.1) was run for the period 18 - 22 August, 2014 (dry season) at a grid spacing of 3 km centered on the city of Manaus. The comparison between simulated and ground-based observed data revealed significant differences in the meteorological fields, for instance, the temperature. Compared to USGS, MODIS classification showed better skill in representing observed temperature for urban areas of Manaus, while the two files showed similar results for nearby areas. The analysis of the files suggests that the better quality of the simulations favorable to the MODIS file is straightly related to its better representation of urban class of land use, which is observed to be not adequately repre- sented by USGS.

Keywords:

Land Use and Land Cover Classification, Regional Modeling Studies, Urban Air Quality

1. Introduction

Land cover classification is an important component of the weather research and forecasting models, especially if the simulations are performed by using coupled chemistry. Spatial distribution of different database of land cover will influence the meteorological variables, which in turn are associated with the transport and dispersion of air pollutants. This influence was noted by [1], wherein observed that the temperature in urban areas was higher than in rural areas. The increase in temperature accelerates the rate of diffusion, which leads to the formation of upward vertical movement causing increased thermal turbulence, generating entrainment of the pollutants from lower levels to higher levels. Another important aspect is the representation of forest class, where the presence of these in a region can change temperature and relative humidity. In addition, accurate representation of forest can influence the concentration of volatile organic compounds in the atmosphere and consequently the secondary chemical compounds [2] [3].

In this study, the impact of using suitable classes of land use and land cover to represent the temperature by regional atmospheric modeling was addressed for Manaus region, Brazil.

2. Materials and Methods

2.1. Study Area

The domain of study includes the urban area of Manaus and its surroundings, with a total area of 232,560 km2 (Figure 1). The city of Manaus is located in the Northern Region of Brazil, in central Amazon, at coordinates 03˚06'07''S and 60˚01'30''W. Manaus has an urbanized area of approximately 230 km2, equivalent to about 0.1% of the selected domain of study. Manaus has an estimated population of about 2 million inhabitants, represent- ing 52% of the total population of the state of Amazonas [4].

2.2. WRF Model

The Weather Research and Forecasting model (WRF, version 3.2.1) is a non-hydrostatic mesoscale prediction and atmospheric simulation system [5]. The WRF code is available at http://www.mmm.ucar.edu/wrf/users. The WRF model was run with a grid spacing of 3 km with 190 × 136 grid points in horizontal domain, centered on the city of Manaus, at 3.07˚S and 59.99˚W. The simulation comprises the period 18 - 22 August, 2014, repre- senting the dry season of the region. The physics configurations that were considered in the simulations are presented in Table 1.

Figure 1. Geographic location of the study area.

Table 1. Physics configurations options in the WRF simulations.

2.3. Data Sources

To evaluate the impact of land cover, two traditional classifications, the United States Geological Survey (USGS) and the Moderate-resolution Imaging Spectroradiometer (MODIS), were used. USGS data are derived from the Advanced Very High Resolution Radiometer (AVHRR) sensor, and measurements based on Normalized Difference Vegetation Index (NDVI) with a resolution of 1.0 km, obtained between from April 1992 to March 1993 [6]. The MODIS-2005, with a spatial resolution of 500 meters, comprises data acquired in 36 spectral bands distributed between the visible and thermal infrared (0.4 - 14.3 μm) [7].

Simulated temperature fields were compared with observations measured in four meteorological stations located in different sites (Figure 2): T1, which was located within the city of Manaus, at National Institute for Amazonian Research (INPA); T3, which was located north of Manacapuru, about 100 km from Manaus, a site of the project Green Ocean Amazon (GOAmazon, 2014); EMBRAPA_AM010, which was located at the Brazilian Agricultural Research Corporation (Embrapa) at AM-010 highway; and EMBRAPA_IRANDUBA, which was located in the municipality of Iranduba, a site associated to the Project REMCLAM Network of Climate Change Amazon.

3. Results and Discussion

Figure 3 shows a comparison between the two land cover databases used in this work. Significant differences can be observed on spatial distribution of land cover classes of the two files. The USGS classification does not recognize the urban class for Manaus city, whereas it is better represented by MODIS. Urban and built up land cover fraction is zero from USGS and 0.1% from MODIS. This later value matches the official values for urbanized area of Manaus. In terms of water bodies, there are significant differences between the two files, highlighting the fact that Balbina Reservoir, with about 2360 km2, is not recognized as a water body by USGS. In addition, there are differences on Evergreen Broadleaf Forest.

The simulated temperature profile was observed to be in good agreement with observed ground-based data, as shown in Figure 4, except for T1 station, which was located in urban area of Manaus. It can be noted that the simulation with USGS file underestimated the values of temperature in urban site. In this case, the better skill showed by MODIS can be attributed to its more adequate representation of urban land cover class. The three sites where a good level of agreement is observed for both, USGS and MODIS, are those located in forested areas.

Comparing the temperature fields for the urban area of Manaus, at 13 LT, it is notable that the presence of urban area generates an increased temperature at the center of city, which is caused by the disturbed natural environment [8]. The maximum simulated temperature at 13 LT, by using MODIS, is 1˚C higher than obtained USGS is used. The parameters Pearson’s Correlation (r), Mean Bias (MB), Root-mean-square error (RMSE) and Skill of Pielke (Spielke) were used to analyze the skill of simulations [9] [10]. The statistical parameters calculated are listed in Table 2. The parameters from USGS and MODIS simulations are similar for the stations T3, EMBRAPA_AM010, EMBRAPA_IRANDUBA. However, for T1, MODIS shows statistical parameters with better quality when compared to USGS. In the case of Skill of Pielke, USGS does not attend the criteria of being representing the atmospheric observed conditions.

Figure 2. Location of meteorological stations in the study region.

Figure 3. Land use and land cover maps from USGS and MODIS. 1: (red) represents urban and built-up land; 2: dryland cropland and pasture; 3: irrigated cropland and pasture; 4: mixed dryland/irrigated cropland and pasture; 5: cropland/grassland mosaic; 6: cropland/woodland mosaic; 7: grassland; 8: shrubland; 9: mixed shrubland/grassland; 10: savanna; deciduous broadleaf forest; 11: deciduous needeleaf forest; 12: deciduous broadleaf forest; 13: evergreen broadleaf forest; 14: evergreen neddleleaf forest; 15: mixed forest; 16: water bodies; 17: herbaceous wetland; 18: wooded wetland.

Table 2. Comparison of statistical parameters for MODIS and USGS simulations for temperature (˚C).

4. Conclusion

The results of this work indicate that differences in files of land cover classification can impact the quality of simulations. The comparison among simulated scenarios by using two traditional databases frequently used in

Figure 4. Comparison between simulated and observation temperatures at four meteorological stations. MODIS (red), USGS (green) and measurements (black).

numerical simulations, USGS and MODIS, show different level of agreement with observed meteorological fields, especially temperature. The results show that a more realistic database of land use and cover is fundamental to get good skills in regional atmospheric simulations, especially the temperature in urban areas, which impact straightly on air quality diagnostics.

Acknowledgements

This work received funding support from CNPq (National Counsel of Technological and Scientific Development, process 404104/2013-4), CAPES (Coordination for the Improvement of Higher Education Personnel) and Araucária Foundation.

Cite this paper

Sameh Adib Abou Rafee,Ana Beatriz Kawashima,Marcos Vinícius Bueno de Morais,Viviana Urbina,Leila Droprinchinski Martins,Jorge Alberto Martins, (2015) Assessing the Impact of Using Different Land Cover Classification in Regional Modeling Studies for the Manaus Area, Brazil. Journal of Geoscience and Environment Protection,03,77-82. doi: 10.4236/gep.2015.36013

References

  1. 1. Oke, T.R. (1987) Boundary Layer Climates. 2ed Edition, Methuen, New York, 435 p.

  2. 2. Kesselmeier, et al. (2000) Atmospheric Volatile Organic Compounds (VOC) at a Remote Tropical Forest Site in Central Amazonia. Atmospheric Environment, 34, 4063-4072. http://dx.doi.org/10.1016/S1352-2310(00)00186-2

  3. 3. Gehlhausen, S.M., Schwartz, M.W. and Augspurger, C.K. (2000) Vegetation and Microclimatic Edge Effects in Two Mixed-Mesophytic Forest Frag-ments. Plant Ecology, 147, 21-35. http://dx.doi.org/10.1023/A:1009846507652

  4. 4. IBGE—Instituto Brasileiro de Geografia e Estatística. Censo Demográfico. http://cidades.ibge.gov.br/xtras/perfil.php?codmun=130260

  5. 5. Skamarock, W.C., et al. (2008) Description of the Advanced Research WRF Version 3. National Center for Atmospheric Research Boulder, Colorado.

  6. 6. Hansen, M. and Reed, B.C. (2000) A Comparison of the IGBP Discover and University of Maryland Global Land Cover Products. International Journal of Remote Sensing, 21, 1365-1374. http://dx.doi.org/10.1080/014311600210218

  7. 7. Schneider, A., Friedl, M.A. and Potere, D. (2009) A New Map of Global Urban Extent from MODIS Data. Environmental Research Letters, 4. http://dx.doi.org/10.1088/1748-9326/4/4/044003

  8. 8. Kalnay, E. and Cai, M. (2003) Impact of Urbanization and Land-Use Change on Climate. Nature, 423, 528-531. http://dx.doi.org/10.1038/nature01675

  9. 9. Pielke, R.A. (2002) Mesoscale Meteorological Modeling. 2nd Edition, International Geophysics Series, Vol. 78, 676.

  10. 10. Hallak, R. and Perreira Filho, A.J. (2001) Metodologia para análise de desempenho de simulacaes de sistemas convectivos na regiao metropolitana de Sao Paulo com o modelo ARPS: sensibilidade a variacoes com os esquemas de adveccao e assimilacao de dados. Revista Brasileira de Meteorologia, 26, 591-608.

NOTES

*Corresponding author.