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- Title
Pan-European climate at convection-permitting scale: a model intercomparison study.
- Authors
Berthou, Ségolène; Kendon, Elizabeth J.; Chan, Steven C.; Ban, Nikolina; Leutwyler, David; Schär, Christoph; Fosser, Giorgia
- Abstract
We investigate the effect of using convection-permitting models (CPMs) spanning a pan-European domain on the representation of precipitation distribution at a climatic scale. In particular we compare two 2.2 km models with two 12 km models run by ETH Zürich (ETH-12 km and ETH-2.2 km) and the Met-Office (UKMO-12 km and UKMO-2.2 km). The two CPMs yield qualitatively similar differences to the precipitation climatology compared to the 12 km models, despite using different dynamical cores and different parameterization packages. A quantitative analysis confirms that the CPMs give the largest differences compared to 12 km models in the hourly precipitation distribution in regions and seasons where convection is a key process: in summer across the whole of Europe and in autumn over the Mediterranean Sea and coasts. Mean precipitation is increased over high orography, with an increased amplitude of the diurnal cycle. We highlight that both CPMs show an increased number of moderate to intense short-lasting events and a decreased number of longer-lasting low-intensity events everywhere, correcting (and often over-correcting) biases in the 12 km models. The overall hourly distribution and the intensity of the most intense events is improved in Switzerland and to a lesser extent in the UK but deteriorates in Germany. The timing of the peak in the diurnal cycle of precipitation is improved. At the daily time-scale, differences in the precipitation distribution are less clear but the greater Alpine region stands out with the largest differences. Also, Mediterranean autumnal intense events are better represented at the daily time-scale in both 2.2 km models, due to improved representation of mesoscale processes.
- Subjects
MODELS &; modelmaking; ALPINE regions; EIDGENOSSISCHE Technische Hochschule; METEOROLOGICAL precipitation
- Publication
Climate Dynamics, 2020, Vol 55, Issue 1/2, p35
- ISSN
0930-7575
- Publication type
Article
- DOI
10.1007/s00382-018-4114-6