Geostatistical Analysis and Mapping of Groundlevel Ozone in a Medium Sized Urban Area
Ground-level tropospheric ozone is one of the air
pollutants of most concern. It is mainly produced by photochemical
processes involving nitrogen oxides and volatile organic compounds
in the lower parts of the atmosphere. Ozone levels become
particularly high in regions close to high ozone precursor emissions
and during summer, when stagnant meteorological conditions with
high insolation and high temperatures are common.
In this work, some results of a study about urban ozone
distribution patterns in the city of Badajoz, which is the largest and
most industrialized city in Extremadura region (southwest Spain) are
shown. Fourteen sampling campaigns, at least one per month, were
carried out to measure ambient air ozone concentrations, during
periods that were selected according to favourable conditions to
ozone production, using an automatic portable analyzer.
Later, to evaluate the ozone distribution at the city, the measured
ozone data were analyzed using geostatistical techniques. Thus, first,
during the exploratory analysis of data, it was revealed that they were
distributed normally, which is a desirable property for the subsequent
stages of the geostatistical study. Secondly, during the structural
analysis of data, theoretical spherical models provided the best fit for
all monthly experimental variograms. The parameters of these
variograms (sill, range and nugget) revealed that the maximum
distance of spatial dependence is between 302-790 m and the
variable, air ozone concentration, is not evenly distributed in reduced
distances. Finally, predictive ozone maps were derived for all points
of the experimental study area, by use of geostatistical algorithms
(kriging). High prediction accuracy was obtained in all cases as
cross-validation showed. Useful information for hazard assessment
was also provided when probability maps, based on kriging
interpolation and kriging standard deviation, were produced.
[1] A. Ribas and J. Pe├▒uelas, "Temporal patterns of surface ozone levels in
different habitats of the North Western Mediterranean basin,"
Atmospheric Environment, vol. 38, pp. 985-992, 2004.
[2] J. Lelieveld, H. Berresheim, S. Borrmann, P.J. Crutzen, F.J. Dentener, H.
Fisher, J. Feichter, P.J. Flatau, J. Heland, R. Holzinger, R. Korrmann, M.
Lawrence, Z. Levin, K.M. Markowicz, N. Mihalopoulos, A. Minikin, V.
Ramanathan, M. de Reus, G.J. Roelofs, H.A. Scheeren, J. Sciare, H.
Schlager, M. Schultz, P. Siegmund, B. Steil, E.G. Stephnou, P. Stier, M.
Traub, C. Warneke, J. Williams, and H. Ziereis, "Global air pollution
crossroads over the Mediterranean," Science, vol. 298, pp. 794-799,
2002.
[3] J. Beck and P. Grennfeld, "Distribution of ozone over Europe," in The
Proccedings of the EUROTRAC Symposium 92, The Hague, The
Netherlands, 1993, pp. 43-58.
[4] M.J. Sanz, V. Calatayud and E. Calvo, "Spatial patternof ozone injury in
Aleppo pine related to air pollution dynamics in a coastal-mountain
region of eastern Spain," Environmental Pollution, vol. 108, pp. 239-
247, 2000.
[5] A. Ribas and J. Pe├▒uelas, "Effects of ethylene diurea as a protective
antiozonant on beans (Phaseolus vulgaris cv Lit) exposed to different
tropospheric ozone doses in Catalonia (NE Spain)," Water, Air and Soil
Pollution, vol. 117, pp. 263-271, 2000.
[6] European Environmental Agency, The European Environment. State and
Outlook 2005, Copenhagen, 2005.
[7] J. Lelieveld and F.J. Denterner, "What controls tropospheric ozone?,"
Journal of Geophysical Research, vol. 105, pp. 3531-3551, 2000.
[8] J.A. Logan, "Tropospheric ozone: seasonal behaviour, trends, and
anthropogenic influence," Journal of Geophysical Research, vol. 90
(D6), pp. 10463-10482, 1985.
[9] A.S. Lefohn, Surface Ozone Exposures and their Effects on Vegetation.
Chelsea: Lewis publishers, 1992.
[10] D. Simpson, "Biogenic emissions in Europe, 2, Implications for ozone
control strategies," Journal of Geophysical Research, vol. 100, pp. 891-
906, 1995.
[11] P.S. Monks, "A review of the observations and origins of the spring
ozone maximum," Atmospheric Environment, vol. 34, pp. 3545-3561,
2000.
[12] M. Peleg, M. Luria, G. Sharf, A. Vanger, G. Kallos, V, Kotroni, K.
Lagouvardos, and M. Varinou, "Observational evidence of an ozone
episode over Grater Athens Area," Atmospheric Environment, vol. 31,
pp. 3969-3983, 1997.
[13] D. Cocchi and C. Trivisano, "Ozone," in Encyclopedia of
environmetrics, New York, 2002, pp. 1518-1523.
[14] C. Dueñas, M.C. Fernández, S. Cañete, J. Carretero, and E. Liger,
"Assessment of ozone variations and meteorological effects in an urban
area in the Mediterranean coast," The Science of the Total Environment,
vol. 299, pp. 97-113.
[15] L.P. Hopkins, K.B. Ensor, and H.S. Rifai, "Empirical evaluation of
ambient ozone interpolation procedures to support exposure models," J.
Air & Waste Management Association, vol. 49, pp. 839-846, 1999.
[16] S. Vardoulakis, N. Gonzalez-Flesca, B.E.A. Fisher, and K. Pericleous,
"Spatial variability of air pollution in the vicinity of a permanent
monitoring station in central Paris," Atmospheric Environment, vol. 39,
pp. 2725-2736, 2005.
[17] A. Coppalle, V. Delmas, and M. Bobbia, "Variability of NOx and NO2
concentrations observed at pedestrian level in the city centre of a
medium sized urban area," Atmospheric Environment, vol. 35, pp. 5361-
5369, 2001.
[18] E.H. Isaaks, and R.M. Srivastava, An Introduction to Applied
Geostatistics. New York: Oxford University Press, 1989.
[19] P. Goovaerts, Geostatistics for Natural Resources Evaluation. New
York: Oxford University Press, 1997.
[20] D. McGrath, C.S. Zhang, and O.T. Carton, "Geostatistical analyses and
hazard assessment on soil lead in Silvermines area, Ireland,"
Environmental Pollution, vol. 127, pp. 239-248, 2004.
[21] A. Korre, S. Durucan, and A. Koutroumani, "Quantitative-spatial
assessment of the risks associated with high Pb loads in soils around
Lavrio, Greece," Applied Geochemistry, vol. 17, pp. 1029-1045, 2002.
[22] P. Goovaerts, "Geostatistical modeling of uncertainty in soil science,"
Geoderma, vol. 103, pp. 3-26, 2001.
[23] D.L: Phillips, D.T., Tingey, E.H., Lee, A.A., Herstrom, and W.E.
Hogsett, "Use of auxiliary data for spatial interpolation of ozone
exposure in southeastern forests," Environmetrics vol. 8, pp. 43-61,
1997.
[24] M. Tayanc, "An assessment of spatial and temporal variation of sulfur
dioxide levels over Istanbul, Turkey," Environmental Pollution, vol.
107, pp. 61-69, 2000.
[25] D.E. Myers, "Interpolation and estimation with spatially located data,"
Chemometrics and Intelligent Laboratory Systems, vol. 11, pp. 209-228,
1991.
[26] C. Carlon, A. Critto, A. Marcomini, and P. Nathanail, "Risk based
characterisation of contaminated industrial site using multivariate and
geostatistical tools," Environmental Pollution, vol. 111, pp. 417-427,
2001.
[27] J.E. Diem, "A critical examination of ozone mapping from a spatialscale
perspective," Environmental Pollution, vol. 125, pp. 369-383,
2003.
[28] P.A. Burrough, and R.A. McDonnell, Principles of Geographical
Information Systems. Oxford: Oxford University Press, 1998.
[29] K. Johnston, J. M. Ver Hoef, K. Krivoruchko, and N. Lucas, Using
ArcGIS Geostatistical Analyst. Redlands, USA: Environmental Systems
Research, 2001.
[30] R. Webster, and M.A. Oliver, Geostatistics for Environmental Scientists.
Brisbane, Australia: John Wiley & Sons Ltd, 2001.
[31] N. Cressie, "Fitting variogram models by weighted least squares,"
Mathematical Geology, vol.17, pp. 563-586, 1985.
[32] C. Deutsch, and A. Journel, Geostatistical Software Library and User-s
Guide. New York: Oxford University Press, 1992.
[33] L.A. McNair, R.A. Harley, and A.G. Russell, "Spatial inhomogeneity in
pollutant concentrations, and their implications for air quality model
evaluation," Atmospheric Environment, vol. 30, pp. 4291-4301, 1996.
[1] A. Ribas and J. Pe├▒uelas, "Temporal patterns of surface ozone levels in
different habitats of the North Western Mediterranean basin,"
Atmospheric Environment, vol. 38, pp. 985-992, 2004.
[2] J. Lelieveld, H. Berresheim, S. Borrmann, P.J. Crutzen, F.J. Dentener, H.
Fisher, J. Feichter, P.J. Flatau, J. Heland, R. Holzinger, R. Korrmann, M.
Lawrence, Z. Levin, K.M. Markowicz, N. Mihalopoulos, A. Minikin, V.
Ramanathan, M. de Reus, G.J. Roelofs, H.A. Scheeren, J. Sciare, H.
Schlager, M. Schultz, P. Siegmund, B. Steil, E.G. Stephnou, P. Stier, M.
Traub, C. Warneke, J. Williams, and H. Ziereis, "Global air pollution
crossroads over the Mediterranean," Science, vol. 298, pp. 794-799,
2002.
[3] J. Beck and P. Grennfeld, "Distribution of ozone over Europe," in The
Proccedings of the EUROTRAC Symposium 92, The Hague, The
Netherlands, 1993, pp. 43-58.
[4] M.J. Sanz, V. Calatayud and E. Calvo, "Spatial patternof ozone injury in
Aleppo pine related to air pollution dynamics in a coastal-mountain
region of eastern Spain," Environmental Pollution, vol. 108, pp. 239-
247, 2000.
[5] A. Ribas and J. Pe├▒uelas, "Effects of ethylene diurea as a protective
antiozonant on beans (Phaseolus vulgaris cv Lit) exposed to different
tropospheric ozone doses in Catalonia (NE Spain)," Water, Air and Soil
Pollution, vol. 117, pp. 263-271, 2000.
[6] European Environmental Agency, The European Environment. State and
Outlook 2005, Copenhagen, 2005.
[7] J. Lelieveld and F.J. Denterner, "What controls tropospheric ozone?,"
Journal of Geophysical Research, vol. 105, pp. 3531-3551, 2000.
[8] J.A. Logan, "Tropospheric ozone: seasonal behaviour, trends, and
anthropogenic influence," Journal of Geophysical Research, vol. 90
(D6), pp. 10463-10482, 1985.
[9] A.S. Lefohn, Surface Ozone Exposures and their Effects on Vegetation.
Chelsea: Lewis publishers, 1992.
[10] D. Simpson, "Biogenic emissions in Europe, 2, Implications for ozone
control strategies," Journal of Geophysical Research, vol. 100, pp. 891-
906, 1995.
[11] P.S. Monks, "A review of the observations and origins of the spring
ozone maximum," Atmospheric Environment, vol. 34, pp. 3545-3561,
2000.
[12] M. Peleg, M. Luria, G. Sharf, A. Vanger, G. Kallos, V, Kotroni, K.
Lagouvardos, and M. Varinou, "Observational evidence of an ozone
episode over Grater Athens Area," Atmospheric Environment, vol. 31,
pp. 3969-3983, 1997.
[13] D. Cocchi and C. Trivisano, "Ozone," in Encyclopedia of
environmetrics, New York, 2002, pp. 1518-1523.
[14] C. Dueñas, M.C. Fernández, S. Cañete, J. Carretero, and E. Liger,
"Assessment of ozone variations and meteorological effects in an urban
area in the Mediterranean coast," The Science of the Total Environment,
vol. 299, pp. 97-113.
[15] L.P. Hopkins, K.B. Ensor, and H.S. Rifai, "Empirical evaluation of
ambient ozone interpolation procedures to support exposure models," J.
Air & Waste Management Association, vol. 49, pp. 839-846, 1999.
[16] S. Vardoulakis, N. Gonzalez-Flesca, B.E.A. Fisher, and K. Pericleous,
"Spatial variability of air pollution in the vicinity of a permanent
monitoring station in central Paris," Atmospheric Environment, vol. 39,
pp. 2725-2736, 2005.
[17] A. Coppalle, V. Delmas, and M. Bobbia, "Variability of NOx and NO2
concentrations observed at pedestrian level in the city centre of a
medium sized urban area," Atmospheric Environment, vol. 35, pp. 5361-
5369, 2001.
[18] E.H. Isaaks, and R.M. Srivastava, An Introduction to Applied
Geostatistics. New York: Oxford University Press, 1989.
[19] P. Goovaerts, Geostatistics for Natural Resources Evaluation. New
York: Oxford University Press, 1997.
[20] D. McGrath, C.S. Zhang, and O.T. Carton, "Geostatistical analyses and
hazard assessment on soil lead in Silvermines area, Ireland,"
Environmental Pollution, vol. 127, pp. 239-248, 2004.
[21] A. Korre, S. Durucan, and A. Koutroumani, "Quantitative-spatial
assessment of the risks associated with high Pb loads in soils around
Lavrio, Greece," Applied Geochemistry, vol. 17, pp. 1029-1045, 2002.
[22] P. Goovaerts, "Geostatistical modeling of uncertainty in soil science,"
Geoderma, vol. 103, pp. 3-26, 2001.
[23] D.L: Phillips, D.T., Tingey, E.H., Lee, A.A., Herstrom, and W.E.
Hogsett, "Use of auxiliary data for spatial interpolation of ozone
exposure in southeastern forests," Environmetrics vol. 8, pp. 43-61,
1997.
[24] M. Tayanc, "An assessment of spatial and temporal variation of sulfur
dioxide levels over Istanbul, Turkey," Environmental Pollution, vol.
107, pp. 61-69, 2000.
[25] D.E. Myers, "Interpolation and estimation with spatially located data,"
Chemometrics and Intelligent Laboratory Systems, vol. 11, pp. 209-228,
1991.
[26] C. Carlon, A. Critto, A. Marcomini, and P. Nathanail, "Risk based
characterisation of contaminated industrial site using multivariate and
geostatistical tools," Environmental Pollution, vol. 111, pp. 417-427,
2001.
[27] J.E. Diem, "A critical examination of ozone mapping from a spatialscale
perspective," Environmental Pollution, vol. 125, pp. 369-383,
2003.
[28] P.A. Burrough, and R.A. McDonnell, Principles of Geographical
Information Systems. Oxford: Oxford University Press, 1998.
[29] K. Johnston, J. M. Ver Hoef, K. Krivoruchko, and N. Lucas, Using
ArcGIS Geostatistical Analyst. Redlands, USA: Environmental Systems
Research, 2001.
[30] R. Webster, and M.A. Oliver, Geostatistics for Environmental Scientists.
Brisbane, Australia: John Wiley & Sons Ltd, 2001.
[31] N. Cressie, "Fitting variogram models by weighted least squares,"
Mathematical Geology, vol.17, pp. 563-586, 1985.
[32] C. Deutsch, and A. Journel, Geostatistical Software Library and User-s
Guide. New York: Oxford University Press, 1992.
[33] L.A. McNair, R.A. Harley, and A.G. Russell, "Spatial inhomogeneity in
pollutant concentrations, and their implications for air quality model
evaluation," Atmospheric Environment, vol. 30, pp. 4291-4301, 1996.
@article{"International Journal of Earth, Energy and Environmental Sciences:58122", author = "F. J. Moral García and P. Valiente González and F. López Rodríguez", title = "Geostatistical Analysis and Mapping of Groundlevel Ozone in a Medium Sized Urban Area", abstract = "Ground-level tropospheric ozone is one of the air
pollutants of most concern. It is mainly produced by photochemical
processes involving nitrogen oxides and volatile organic compounds
in the lower parts of the atmosphere. Ozone levels become
particularly high in regions close to high ozone precursor emissions
and during summer, when stagnant meteorological conditions with
high insolation and high temperatures are common.
In this work, some results of a study about urban ozone
distribution patterns in the city of Badajoz, which is the largest and
most industrialized city in Extremadura region (southwest Spain) are
shown. Fourteen sampling campaigns, at least one per month, were
carried out to measure ambient air ozone concentrations, during
periods that were selected according to favourable conditions to
ozone production, using an automatic portable analyzer.
Later, to evaluate the ozone distribution at the city, the measured
ozone data were analyzed using geostatistical techniques. Thus, first,
during the exploratory analysis of data, it was revealed that they were
distributed normally, which is a desirable property for the subsequent
stages of the geostatistical study. Secondly, during the structural
analysis of data, theoretical spherical models provided the best fit for
all monthly experimental variograms. The parameters of these
variograms (sill, range and nugget) revealed that the maximum
distance of spatial dependence is between 302-790 m and the
variable, air ozone concentration, is not evenly distributed in reduced
distances. Finally, predictive ozone maps were derived for all points
of the experimental study area, by use of geostatistical algorithms
(kriging). High prediction accuracy was obtained in all cases as
cross-validation showed. Useful information for hazard assessment
was also provided when probability maps, based on kriging
interpolation and kriging standard deviation, were produced.", keywords = "Kriging, map, tropospheric ozone, variogram.", volume = "4", number = "1", pages = "25-12", }
