KIT, Campus Süd, Otto-Lehmann-Hörsaal, Physik-Flachbau (Geb. 30.22) und online
Dr. Felix Fundel, Deutscher Wetterdienst, Offenbach
Verification is an essential tool used for monitoring, communicating and further developing the quality of weather prediction systems. The questions that need to be answered by verification are diverse and so is the variety of methods that have to be provided. In this talk, I will give an insight into how verification is used in DWD's meteorological modeling division. The presentation will cover aspects concerning the observations, methods and tools that are used, the challenges we are faced with when interpreting results and some model insights obtained from a longer-lasting, systematic and objective evaluation of forecasts.
KIT, Campus Nord, IMK, Geb. 435, Seminarraum 2.05 und online
Prof. Dr. Justus Notholt, Universität Bremen
tbd
Geb. 30.23, Raum 13/2 und online
(1) Viktoria Dürlich
If you are interested in the zoom link, please contact vdurlich@gmail.com .
KIT Campus North, Building 435 Room 2.05
(1) Dorothea Schwärzel (2) Melina Sebisch (3) Christian Schröder (4) tbd
(1) Forecast uncertainty growth in warm conveyor belts in neural network weather prediction model (2) tbd (3) Master Thesis: Impact of climate change on the Rossby wave activity over the Northern Hemisphere and impacts to temperature Extremes over Europe (4) tbd
KIT Campus Nord, IMK-AAF
Gebäude 326, Raum 150
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Dr. Mehmet Goekkaya, University of Augsburg, Environmental Medicine
KIT, Campus Süd, Otto-Lehmann-Hörsaal, Physik-Flachbau (Geb. 30.22) und online
Prof. Dr. Sue Gray, University of Reading
tbd
Campus Süd, Otto-Lehmann-Hörsaal und online
Dr. Raphaela Vogel, Universität Hamburg
Mesoscale processes like cold pools and gust fronts occur everywhere on Earth and they are an essential element of severe storms. But now we realize that they might also be relevant for climate. The multi-scale interactions in which mesoscale processes are interwoven, from the mm-scale of rain drops to the large-scale circulation, were long out of the range accessible to both traditional Earth system models and high-resolution large-eddy simulations. Emerging tools like global coupled storm-resolving simulations, together with new observations and innovative methods to extract process-oriented products now offer the basis for critical advances in understanding the role of mesoscale processes for the radiative budget and hydrological cycle. In this presentation, I will show recent results demonstrating the importance of shallow mesoscale circulations and cold pools for cloud amount and cloud organization in the trades, and discuss two new tools that we’re developing to advance the physical understanding of the role of mesoscale processes for the fate of trade cumulus clouds.
Mesoscale processes like cold pools and gust fronts occur everywhere on Earth and they are an essential element of severe storms. But now we realize that they might also be relevant for climate. The multi-scale interactions in which mesoscale processes are interwoven, from the mm-scale of rain drops to the large-scale circulation, were long out of the range accessible to both traditional Earth system models and high-resolution large-eddy simulations. Emerging tools like global coupled storm-resolving simulations, together with new observations and innovative methods to extract process-oriented products now offer the basis for critical advances in understanding the role of mesoscale processes for the radiative budget and hydrological cycle. In this presentation, I will show recent results demonstrating the importance of shallow mesoscale circulations and cold pools for cloud amount and cloud organization in the trades, and discuss two new tools that we’re developing to advance the physical understanding of the role of mesoscale processes for the fate of trade cumulus clouds.
Geb. 30.23, Raum 13/2 und online
(1) Miriam Bentke
If you are interested in the zoom link, please contact miriam.bentke@student.kit.edu .
KIT Campus North, Building 435 Room 2.05
(1) Yangfan Zhou (2) Charlotte Wedler (3) Maurus Borne (4) Federico Stainoh, Chair: Katharina Küpfer
(1) Master Thesis: Impact of climate change on the Rossby wave activity over the Northern Hemisphere and impacts to temperature Extremes over Europe (2) Master Thesis: Physical constraints on the emission of water vapor and ash from Hunga Tonga eruption January 2022 (3) tbd (4) tbd
Raum 2.05, Gebäude 435, KIT Campus Nord und via ZOOM
Dr. M. Rami Alfarra, Hamad Bin Khalifa University, Qatar, Qatar Environment and Energy Research Institute
Campus Süd, Otto-Lehmann-Hörsaal und online
Dr. Annette Miltenberger, Universität Mainz
The moisture content and vertical distribution in the extratropical UTLS is important for radiative properties in particular with a perspective to anticipated change of tropopause height and moisture content due to rising greenhouse gas concentrations. We present a Lagrangian perspective on various processes that control the extratropical UTLS moisture content including deep convection and warm-conveyor belts as well as cloud and mixing processes close to the local tropopause. The analysis combines various data sources on UTLS moisture including high-resolution ICON simulation and ERA5, but also observational data from aircraft and satellite.
Geb. 30.23, Raum 13/2 und online
(1) Tabea Unser
If you are interested in the zoom link, please contact tabea.unser@student.kit.edu .
Raum 2.05, Gebäude 435, KIT Campus Nord und via ZOOM
Prof. Martin King, Royal Holloway University of London, Earth Sciences Department
The top of the atmosphere reflectivity of the planet, depends in part, on the optical properties of aerosol in the atmosphere. Frequently atmospheric chemists use chemical proxies for aerosol and here we describe a series of experiment using optical trapping with material extracted from atmospheric filter samples. The experiments demonstrating to a first approximation that organic matter may for core-shell morphologies, have refractive indexes that vary with location and that thin films on aerosol have chemical removal rates comparable to mechanical removal rates from the atmosphere. Basic radiative transfer modelling also demonstrates that thin organic films on atmospheric aerosol may have appreciable effects on planetary reflectivity. We will also show some early data that near-field scattering effects between pairs of aerosol particles predicted by theory (T-matrix) may not agree with experiment.
KIT, Campus Süd, Otto-Lehmann-Hörsaal, Physik-Flachbau (Geb. 30.22) und online
Dr. Tanja Stanelle, EBP, Zürich
tbd