Quantitative relationship between Meteosat WV data and positive potential vorticity anomalies: a case study over the Mediterranean

Christo G Georgiev

doi:10.1017/S1350482799001024

Abstract

The correlation between Meteosat water vapour (WV) data and positive anomalies of potential vorticity (PV) is investigated using a case study involving cyclogenesis in the Alpine region and a north-west African depression. Correlation analyses are performed at different isobaric surfaces in the middle and upper troposphere for two latitudinal belts (25–35° N – ‘southern’, and 35–52.5°N – ‘northern’). A significant correlation is obtained at 500 hPa (correlation coefficient range: 0.58–0.64). Linear regression models are fitted to the samples from the northern and southern belts. On the basis of these results, the use of WV data as a tool for detection of errors in model-derived PV fields is discussed. It is concluded that, though some of the discrepancies between PV fields and WV images could be due to errors in the model analysis or prognosis, some mismatches are possibly due to the variable sensitivity of the WV channel because of the changes in pressure over the commonly used PV fields. It is suggested that the comparison of WV data with the field of positive PV anomalies at 500 hPa might be another approach to help solve the problem of verifying and validating numerical output.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Swarbrick, S J 2001. Applying the relationship between potential vorticity fields and water vapour imagery to adjust initial conditions in NWP. Meteorological Applications, Vol. 8, Issue. 2, p. 221.

Georgiev, Christo G and Martín, Francisco 2001. Use of potential vorticity fields, Meteosat water vapour imagery and pseudo water vapour images for evaluating numerical model behaviour. Meteorological Applications, Vol. 8, Issue. 1, p. 57.

Porcú, Federico Caracciolo, Clelia and Prodi, Franco 2003. Cloud systems leading to flood events in Europe: an overview and classification. Meteorological Applications, Vol. 10, Issue. 3, p. 217.

Krennert, T. and Zwatz-Meise, V. 2003. Initiation of convective cells in relation to water vapour boundaries in satellite images. Atmospheric Research, Vol. 67-68, Issue. , p. 353.

2005. Weather Analysis and Forecasting. p. 171.

Michel, Y. and Bouttier, F. 2006. Automated tracking of dry intrusions on satellite water vapour imagery and model output. Quarterly Journal of the Royal Meteorological Society, Vol. 132, Issue. 620, p. 2257.

Porcù, F. Carrassi, A. Medaglia, C. M. Prodi, F. and Mugnai, A. 2007. A study on cut-off low vertical structure and precipitation in the Mediterranean region. Meteorology and Atmospheric Physics, Vol. 96, Issue. 1-2, p. 121.

Argence, Sébastien Lambert, Dominique Richard, Evelyne Pierre Chaboureau, Jean Philippe Arbogast, Jean and Maynard, Karine 2009. Improving the numerical prediction of a cyclone in the Mediterranean by local potential vorticity modifications. Quarterly Journal of the Royal Meteorological Society, Vol. 135, Issue. 641, p. 865.

Michel, Yann 2010. Data Assimilation of Tropopause Height Using Dry Intrusion Observations. Monthly Weather Review, Vol. 138, Issue. 1, p. 101.

Clark, M. R. 2011. An observational study of the exceptional ‘Ottery St Mary’ thunderstorm of 30 October 2008. Meteorological Applications, Vol. 18, Issue. 2, p. 137.

Kim, In-Hye Kwon, Tae-Yong and Kim, Deok-Rae 2012. MTSAT Satellite Image Features on the Sever Storm Events in Yeongdong Region. Atmosphere, Vol. 22, Issue. 1, p. 29.

Kwon, Tae-Yong and Lee, Jeong-Soon 2013. Satellite Image Analysis of Convective Cell in the Chuseok Heavy Rain of 21 September 2010. Korean Journal of Remote Sensing, Vol. 29, Issue. 4, p. 423.

Kouroutzoglou, J. Flocas, H. A. Hatzaki, M. Keay, K. Simmonds, I. and Mavroudis, A. 2015. On the dynamics of a case study of explosive cyclogenesis in the Mediterranean. Meteorology and Atmospheric Physics, Vol. 127, Issue. 1, p. 49.

2016. Weather Analysis and Forecasting. p. 327.

Miglietta, M. M. Cerrai, D. Laviola, S. Cattani, E. and Levizzani, V. 2017. Potential vorticity patterns in Mediterranean “hurricanes”. Geophysical Research Letters, Vol. 44, Issue. 5, p. 2537.

Torresani, Michele Masiello, Guido Vendrame, Nadia Gerosa, Giacomo Falocchi, Marco Tomelleri, Enrico Serio, Carmine Rocchini, Duccio and Zardi, Dino 2022. Correlation Analysis of Evapotranspiration, Emissivity Contrast and Water Deficit Indices: A Case Study in Four Eddy Covariance Sites in Italy with Different Environmental Habitats. Land, Vol. 11, Issue. 11, p. 1903.

Georgiev, Christo G. Tjemkes, Stephen A. Karagiannidis, Athanasios Prieto, Jose and Lagouvardos, Konstantinos 2022. Observational Analyses of Dry Intrusions and Increased Ozone Concentrations in the Environment of Wildfires. Atmosphere, Vol. 13, Issue. 4, p. 597.

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Quantitative relationship between Meteosat WV data and positive potential vorticity anomalies: a case study over the Mediterranean

Abstract

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Quantitative relationship between Meteosat WV data and positive potential vorticity anomalies: a case study over the Mediterranean

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