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191 results on '"Zängl, Günther"'

1. Crucial Role of Obliquely Propagating Gravity Waves in the Quasi-Biennial Oscillation Dynamics

Author

Kim, Young-Ha, Voelker, Georg S., Bölöni, Gergely, Zängl, Günther, and Achatz, Ulrich

Subjects
Physics - Atmospheric and Oceanic Physics
Abstract

In climate modelling, the reality of simulated flows in the middle atmosphere is largely affected by the model's representation of gravity wave processes that are unresolved, while these processes are usually simplified to facilitate computations. The simplification commonly applied in existing climate models is to neglect wave propagation in horizontal direction and time. Here we use a model that fully represents the propagation of unresolved waves in all directions, thereby elucidating its dynamical effect upon the most important climate mode in the tropical stratosphere, namely the quasi-biennial oscillation. Our simulation shows that the waves at the equatorial stratosphere, which are known to drive this climate mode, can originate far away from the equator in the troposphere. The waves propagating obliquely toward the equator are found to play a huge role in the phase progression of the quasi-biennial oscillation as well as in its penetration into the lower stratosphere. Such waves will require further attention, given that current climate models are struggling to simulate the quasi-biennial oscillation down to the lower stratosphere, which may be needed to reproduce its observed impacts on the surface climate., Comment: Final version published in Atmos. Chem. Phys

Published
2023
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2. MS-GWaM: A 3-dimensional transient gravity wave parametrization for atmospheric models

Author

Voelker, Georg S., Bölöni, Gergely, Kim, Young-Ha, Zängl, Günther, and Achatz, Ulrich

Subjects
Physics - Fluid Dynamics, Physics - Geophysics
Abstract

Parametrizations for internal gravity waves in atmospheric models are traditionally subject to a number of simplifications. Most notably, they rely on both neglecting wave propagation and advection in the horizontal direction (single-column assumption) and an instantaneous balance in the vertical direction (steady-state assumption). While these simplifications are well justified to cover some essential dynamic effects and keep the computational effort small it has been shown that both mechanisms are potentially significant. In particular, the recently introduced Multiscale Gravity Wave Model (MS-GWaM) successfully applied ray tracing methods in a novel type of transient but columnar internal gravity wave parameterization (MS-GWaM-1D). We extend this concept to a three-dimensional version of the parameterization (MS-GWaM-3D) to simulate subgrid-scale non-orographic internal gravity waves. The resulting global wave model -- implemented into the weather-forecast and climate code ICON -- contains three-dimensional transient propagation with accurate flux calculations, a latitude-dependent background source, and convectively generated waves. MS-GWaM-3D helps reproducing expected temperature and wind patterns in the mesopause region in the climatological zonal mean state and thus proves a viable IGW parameterization. Analyzing the global wave action budget, we find that horizontal wave propagation is as important as vertical wave propagation. The corresponding wave refraction includes previously missing but well-known effects such as wave refraction into the polar jet streams. On a global scale, three-dimensional wave refraction leads to a horizontal flow-dependent redistribution of waves such that the structures of the zonal mean wave drag and consequently the zonal mean winds are modified., Comment: Revised version after major revisions in peer review; This Work has been submitted to the Journal of Atmospheric Sciences. Copyright in this Work may be transferred without further notice

Published
2023

4. MS-GWaM: A Three-Dimensional Transient Gravity Wave Parametrization for Atmospheric Models.

Author

Voelker, Georg S., Bölöni, Gergely, Kim, Young-Ha, Zängl, Günther, and Achatz, Ulrich

Subjects
GRAVITY waves, ATMOSPHERIC models, ATMOSPHERIC waves, INTERNAL waves, ROSSBY waves, JET streams
Abstract

Parameterizations for internal gravity waves in atmospheric models are traditionally subject to a number of simplifications. Most notably, they rely on both neglecting wave propagation and advection in the horizontal direction (single-column assumption) and an instantaneous balance in the vertical direction (steady-state assumption). While these simplifications are well justified to cover some essential dynamic effects and keep the computational effort small, it has been shown that both mechanisms are potentially significant. In particular, the recently introduced Multiscale Gravity Wave Model (MS-GWaM) successfully applied ray-tracing methods in a novel type of transient but columnar internal gravity wave parameterization (MS-GWaM-1D). We extend this concept to a three-dimensional version of the parameterization (MS-GWaM-3D) to simulate subgrid-scale nonorographic internal gravity waves. The resulting global wave model—implemented into the weather forecast and climate code Icosahedral Nonhydrostatic (ICON)—contains three-dimensional transient propagation with accurate flux calculations, a latitude-dependent background source, and convectively generated waves. MS-GWaM-3D helps reproduce expected temperature and wind patterns in the mesopause region in the climatological zonal mean state and thus proves a viable internal gravity wave (IGW) parameterization. Analyzing the global wave action budget, we find that horizontal wave propagation is as important as vertical wave propagation. The corresponding wave refraction includes previously missing but well-known effects such as wave refraction into the polar jet streams. On a global scale, three-dimensional wave refraction leads to a horizontal flow-dependent redistribution of waves such that the structures of the zonal mean wave drag and consequently the zonal mean winds are modified. [ABSTRACT FROM AUTHOR]

Published
2024
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5. The Community Foehn Classification Experiment

Author

Mayr, Georg J., Plavcan, David, Armi, Laurence, Elvidge, Andrew, Grisogono, Branko, Horvath, Kristian, Jackson, Peter, Neururer, Alfred, Seibert, Petra, Steenburgh, James W., Stiperski, Ivana, Sturman, Andrew, Večenaj, Željko, Vergeiner, Johannes, Vosper, Simon, and Zängl, Günther

Published
2018

6. Systematic Errors in Weather and Climate Models: Challenges and Opportunities in Complex Coupled Modeling Systems

Author

Frassoni, Ariane, primary, Reynolds, Carolyn, additional, Wedi, Nils, additional, Bouallègue, Zied Ben, additional, Caltabiano, Antonio Caetano Vaz, additional, Casati, Barbara, additional, Christophersen, Jonathan A., additional, Coelho, Caio A. S., additional, De Falco, Chiara, additional, Doyle, James D., additional, Fernandes, Laís G., additional, Forbes, Richard, additional, Janiga, Matthew A., additional, Klocke, Daniel, additional, Magnusson, Linus, additional, McTaggart-Cowan, Ron, additional, Pakdaman, Morteza, additional, Rushley, Stephanie S., additional, Verhoef, Anne, additional, Yang, Fanglin, additional, and Zängl, Günther, additional

Published
2023
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8. A Compact Parallel Algorithm for Spherical Delaunay Triangulations

Author

Prill, Florian, Zängl, Günther, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Wyrzykowski, Roman, editor, Deelman, Ewa, editor, Dongarra, Jack, editor, Karczewski, Konrad, editor, Kitowski, Jacek, editor, and Wiatr, Kazimierz, editor

Published
2016
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10. Crucial role of obliquely propagating gravity waves in the quasi-biennial oscillation dynamics.

Author

Kim, Young-Ha, Voelker, Georg Sebastian, Bölöni, Gergely, Zängl, Günther, and Achatz, Ulrich

Subjects
GRAVITY waves, ATMOSPHERIC models, MODES of variability (Climatology), THEORY of wave motion, OSCILLATIONS, ROSSBY waves
Abstract

​​​​​​​In climate modelling, the reality of simulated flows in the middle atmosphere is largely affected by the model's representation of gravity wave processes that are unresolved, while these processes are usually simplified to facilitate computations. The simplification commonly applied in existing climate models is to neglect wave propagation in horizontal direction and time. Here we use a model that fully represents the propagation of unresolved waves in all directions, thereby elucidating its dynamical effect upon the most important climate mode in the tropical stratosphere, i.e. the quasi-biennial oscillation. Our simulation shows that the waves in the equatorial stratosphere, which are known to drive this climate mode, can originate far away from the Equator in the troposphere. The waves propagating obliquely toward the Equator are found to play a huge role in the phase progression of the quasi-biennial oscillation as well as in its penetration into the lower stratosphere. Such waves will require further attention, given that current climate models are struggling to simulate the quasi-biennial oscillation down to the lower stratosphere, which may be needed to reproduce its observed impacts on the surface climate. [ABSTRACT FROM AUTHOR]

Published
2024
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18. ICON-Seamless, the development of a novel Earth System Model based on ICON for time scales from weather to climate

Author

Früh, Barbara, primary, Potthast, Roland, additional, Müller, Wolfgang, additional, Korn, Peter, additional, Brienen, Susanne, additional, Fröhlich, Kristina, additional, Helmert, Jürgen, additional, Köhler, Martin, additional, Lorenz, Stephan, additional, Pham, Trang Van, additional, Pohlmann, Holger, additional, Schlemmer, Linda, additional, Schnur, Reiner, additional, Schulz, Jan-Peter, additional, Sgoff, Christine, additional, Vogel, Bernhard, additional, Wirth, Roland, additional, and Zängl, Günther, additional

Published
2022
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19. ICON NWP on GPUs

Author

Jacob, Marek, primary, Alexeev, Dmitry, additional, Dietlicher, Remo, additional, Cherkas, Victoria, additional, Germann, Elsa, additional, Gessler, Fabian, additional, Hupp, Daniel, additional, Jocksch, Andreas, additional, Lapillonne, Xavier, additional, Müller, Christoph, additional, Osuna, Carlos, additional, Reinert, Daniel, additional, Sawyer, William, additional, Schättler, Ulrich, additional, and Zängl, Günther, additional

Published
2022
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24. ICON-waves: towards an atmosphere-waves coupled

Author

Dobrynin, Mikhail, primary, Reinert, Daniel, additional, Prill, Florian, additional, Zängl, Günther, additional, Sievers, Oliver, additional, Bruns, Thomas, additional, Günther, Heinz, additional, and Behrens, Arno, additional

Published
2021
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25. ICON-seamless: die Entwicklung eines neuen Erdsystemmodells basierend auf ICON für alle Zeitskalen, von Wettervorhersagen bis Klimaprognosen

Author

Potthast, Roland, primary, Müller, Wolfgang, additional, Früh, Barbara, additional, Korn, Peter, additional, Brienen, Susanne, additional, Fröhlich, Kristina, additional, Helmert, Jürgen, additional, Köhler, Martin, additional, Lorenz, Stephan, additional, Pham, Trang Van, additional, Pohlmann, Holger, additional, Schlemmer, Linda, additional, Schnur, Reiner, additional, Schulz, Jan-Peter, additional, Sgoff, Christine, additional, Vogel, Bernhard, additional, Wirth, Roland, additional, and Zängl, Günther, additional

Published
2021
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28. Improved Circulation in the Northern Hemisphere by Adjusting Gravity Wave Drag Parameterizations in Seasonal Experiments With ICON-NWP

Author

Köhler, Raphael, Handorf, Dörthe, Jaiser, Ralf, Dethloff, Klaus, Zängl, Günther, Majewski, Detlev, Rex, Markus, Köhler, Raphael, Handorf, Dörthe, Jaiser, Ralf, Dethloff, Klaus, Zängl, Günther, Majewski, Detlev, and Rex, Markus

Abstract

The stratosphere is one of the main potential sources for subseasonal to seasonal predictability in midlatitudes in winter. The ability of an atmospheric model to realistically simulate the stratospheric dynamics is essential in order to move forward in the field of seasonal predictions in midlatitudes. Earlier studies with the ICOsahedral Nonhydrostatic atmospheric model (ICON) point out that stratospheric westerlies in ICON are underestimated. This is the first extensive study on the evaluation of Northern Hemisphere stratospheric winter circulation with ICON in numerical weather prediction (NWP) mode. Seasonal experiments with the default setup are able to reproduce the basic climatology of the stratospheric polar vortex. However, westerlies are too weak and major stratospheric warmings too frequent in ICON. Both a reduction of the nonorographic, and a reduction of the orographic gravity wave and wake drag lead to a strengthening of the stratospheric vortex and a bias reduction, in particular in January. However, the effect of the nonorographic gravity wave drag scheme on the stratosphere is stronger. Stratosphere-troposphere coupling is intensified and more realistic due to a reduced gravity wave drag. Furthermore, an adjustment of the subgrid-scale orographic drag parameterization leads to a significant error reduction in the mean sea level pressure. As a result of these findings, we present our current suggested improved setup for seasonal experiments with ICON-NWP.

Published
2021

29. FLOHOF 2007: an overview of the mesoscale meteorological field campaign at Hofsjökull, Central Iceland

Author

Reuder, Joachim, Ablinger, Markus, Ágústsson, Hálfdán, Brisset, Pascal, Brynjólfsson, Sveinn, Garhammer, Markus, Jóhannesson, Tómas, Jonassen, Marius O., Kühnel, Rafael, Lämmlein, Stephan, de Lange, Tor, Lindenberg, Christian, Malardel, Sylvie, Mayer, Stephanie, Müller, Martin, Ólafsson, Haraldur, Rögnvaldsson, Ólafur, Schäper, Wolfgang, Spengler, Thomas, Zängl, Günther, and Egger, Joseph

Published
2012
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34. ICON Tutorial 2020: Working with the ICON Model

Author

Prill, Florian, Reinert, Daniel, Rieger, Daniel, and Zängl, Günther

Subjects
InformationSystems_INFORMATIONINTERFACESANDPRESENTATION(e.g.,HCI), ComputerApplications_MISCELLANEOUS
Abstract

The ICON tutorial is intended to help new users to get started with ICON, but also serves as a reference for more experienced users.

Published
2020
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40. Reports on ICON 004: ecRad in ICON - Implementation Overview

Author

Rieger, Daniel, Köhler, Martin, Hogan, Robin J., Schäfer, Sophia A.K., Seifert, Axel, de Lozar, Alberto, and Zängl, Günther

Abstract

The new radiation package ecRad from ECMWF (European Centre for Medium-RangeWeather Forecasts) has been successfully implemented into the numerical weather prediction(NWP) physics package of ICON. This article describes the concept of the implementation, lists assumptions that have been made and provides an overview on the available namelistsettings to control ecRad. First results are presented including a comparison with the RRTM (Rapid Radiative Transfer Model) radiation scheme currently used operationally for NWP and a comparison with CERES (Clouds and the Earth’s Radiant Energy System) observational data. Keywords: radiation, NWP, ecRad

Published
2019
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41. ICON-ART 2.1: a flexible tracer framework and its application for composition studies in numerical weather forecasting and climate simulations

Author

Schröter, Jennifer, Rieger, Daniel, Stassen, Christian, Vogel, Heike, Weimer, Michael, Werchner, Sven, Förstner, Jochen, Prill, Florian, Reinert, Daniel, Zängl, Günther, Giorgetta, Marco, Ruhnke, Roland, Vogel, Bernhard, and Braesicke, Peter

Subjects
Earth sciences, ddc:550
Abstract

Atmospheric composition studies on weather and climate timescales require flexible, scalable models. The ICOsahedral Nonhydrostatic model with Aerosols and Reactive Trace gases (ICON-ART) provides such an environment. Here, we introduce the most up-to-date version of the flexible tracer framework for ICON-ART and explain its application in one numerical weather forecast and one climate related case study. We demonstrate the implementation of idealised tracers and chemistry tendencies of different complexity using the ART infrastructure. Using different ICON physics configurations for weather and climate with ART, we perform integrations on different timescales, illustrating the model’s performance. First, we present a hindcast experiment for the 2002 ozone hole split with two different ozone chemistry schemes using the numerical weather prediction physics configuration. We compare the hindcast with observations and discuss the confinement of the vortex split using an idealised tracer diagnostic. Secondly, we study AMIPtype integrations using a simplified chemistry scheme in conjunction with the climate physics configuration. We use two different simulations: the interactive simulation, where modelled ozone is coupled back to the radiation scheme, and the non-interactive simulation that uses a default background climatology of ozone. Additionally, we introduce changes of water vapour by methane oxidation for the interactive simulation. We discuss the impact of stratospheric ozone and water vapour variations in the interactive and non-interactive integrations on the water vapour tape recorder, as a measure of tropical upwelling changes. Additionally we explain the seasonal evolution and latitudinal distribution of the age of air. The age of air is a measure of the strength of the meridional overturning circulation with young air in the tropical upwelling region and older air in polar winter downwelling regions. We conclude that our flexible tracer framework allows for tailor-made configurations of ICON-ART in weather and climate applications that are easy to configure and run well.

Published
2018

45. ICON-ART 2.1: a flexible tracer framework and its application for composition studies in numerical weather forecasting and climate simulations

Author

Schröter, Jennifer, primary, Rieger, Daniel, additional, Stassen, Christian, additional, Vogel, Heike, additional, Weimer, Michael, additional, Werchner, Sven, additional, Förstner, Jochen, additional, Prill, Florian, additional, Reinert, Daniel, additional, Zängl, Günther, additional, Giorgetta, Marco, additional, Ruhnke, Roland, additional, Vogel, Bernhard, additional, and Braesicke, Peter, additional

Published
2018
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46. Large-eddy simulations over Germany using ICON: a comprehensive evaluation

Author

Heinze, Rieke, Dipankar, Anurag, Henken, Cintia Carbajal, Moseley, Christopher, Sourdeval, Odran, Trömel, Silke, Xie, Xinxin, Adamidis, Panos, Ament, Felix, Baars, Holger, Barthlott, Christian, Behrendt, Andreas, Blahak, Ulrich, Bley, Sebastian, Brdar, Slavko, Brueck, Matthias, Crewell, Susanne, Deneke, Hartwig, Di Girolamo, Paolo, Evaristo, Raquel, Fischer, Jürgen, Frank, Christopher, Friederichs, Petra, Göcke, Tobias, Gorges, Ksenia, Hande, Luke, Hanke, Moritz, Hansen, Akio, Hege, Hans-Christian, Hoose, Corinna, Jahns, Thomas, Kalthoff, Norbert, Klocke, Daniel, Kneifel, Stefan, Knippertz, Peter, Kuhn, Alexander, Laar, Thriza van, Macke, Andreas, Maurer, Vera, Mayer, Bernhard, Meyer, Catrin I., Muppa, Shravan K., Neggers, Roeland A.J., Orlandi, Emiliano, Pantillon, Florian, Pospichal, Bernhard, Röber, Niklas, Scheck, Leonhard, Seifert, Axel, Seifert, Patric, Senf, Fabian, Siligam, Pavan, Simmer, Clemens, Steinke, Sandra, Stevens, Björn, Wapler, Kathrin, Weniger, Michael, Wulfmeyer, Volker, Zängl, Günther, Zhang, Dan, Quaas, Johannes, Heinze, Rieke, Dipankar, Anurag, Henken, Cintia Carbajal, Moseley, Christopher, Sourdeval, Odran, Trömel, Silke, Xie, Xinxin, Adamidis, Panos, Ament, Felix, Baars, Holger, Barthlott, Christian, Behrendt, Andreas, Blahak, Ulrich, Bley, Sebastian, Brdar, Slavko, Brueck, Matthias, Crewell, Susanne, Deneke, Hartwig, Di Girolamo, Paolo, Evaristo, Raquel, Fischer, Jürgen, Frank, Christopher, Friederichs, Petra, Göcke, Tobias, Gorges, Ksenia, Hande, Luke, Hanke, Moritz, Hansen, Akio, Hege, Hans-Christian, Hoose, Corinna, Jahns, Thomas, Kalthoff, Norbert, Klocke, Daniel, Kneifel, Stefan, Knippertz, Peter, Kuhn, Alexander, Laar, Thriza van, Macke, Andreas, Maurer, Vera, Mayer, Bernhard, Meyer, Catrin I., Muppa, Shravan K., Neggers, Roeland A.J., Orlandi, Emiliano, Pantillon, Florian, Pospichal, Bernhard, Röber, Niklas, Scheck, Leonhard, Seifert, Axel, Seifert, Patric, Senf, Fabian, Siligam, Pavan, Simmer, Clemens, Steinke, Sandra, Stevens, Björn, Wapler, Kathrin, Weniger, Michael, Wulfmeyer, Volker, Zängl, Günther, Zhang, Dan, and Quaas, Johannes

Abstract

Large-eddy simulations (LES) with the new ICOsahedral Non-hydrostatic atmosphere model (ICON) covering Germany are evaluated for four days in spring 2013 using observational data from various sources. Reference simulations with the established Consortium for Small-scale Modelling (COSMO) numerical weather prediction model and further standard LES codes are performed and used as a reference. This comprehensive evaluation approach covers multiple parameters and scales, focusing on boundary-layer variables, clouds and precipitation. The evaluation points to the need to work on parametrizations influencing the surface energy balance, and possibly on ice cloud microphysics. The central purpose for the development and application of ICON in the LES configuration is the use of simulation results to improve the understanding of moist processes, as well as their parametrization in climate models. The evaluation thus aims at building confidence in the model's ability to simulate small- to mesoscale variability in turbulence, clouds and precipitation. The results are encouraging: the high-resolution model matches the observed variability much better at small- to mesoscales than the coarser resolved reference model. In its highest grid resolution, the simulated turbulence profiles are realistic and column water vapour matches the observed temporal variability at short time-scales. Despite being somewhat too large and too frequent, small cumulus clouds are well represented in comparison with satellite data, as is the shape of the cloud size spectrum. Variability of cloud water matches the satellite observations much better in ICON than in the reference model. In this sense, it is concluded that the model is fit for the purpose of using its output for parametrization development, despite the potential to improve further some important aspects of processes that are also parametrized in the high-resolution model.

Published
2017

47. Large‐eddy simulations over Germany using ICON: a comprehensive evaluation

Author

Heinze, Rieke, primary, Dipankar, Anurag, additional, Henken, Cintia Carbajal, additional, Moseley, Christopher, additional, Sourdeval, Odran, additional, Trömel, Silke, additional, Xie, Xinxin, additional, Adamidis, Panos, additional, Ament, Felix, additional, Baars, Holger, additional, Barthlott, Christian, additional, Behrendt, Andreas, additional, Blahak, Ulrich, additional, Bley, Sebastian, additional, Brdar, Slavko, additional, Brueck, Matthias, additional, Crewell, Susanne, additional, Deneke, Hartwig, additional, Di Girolamo, Paolo, additional, Evaristo, Raquel, additional, Fischer, Jürgen, additional, Frank, Christopher, additional, Friederichs, Petra, additional, Göcke, Tobias, additional, Gorges, Ksenia, additional, Hande, Luke, additional, Hanke, Moritz, additional, Hansen, Akio, additional, Hege, Hans‐Christian, additional, Hoose, Corinna, additional, Jahns, Thomas, additional, Kalthoff, Norbert, additional, Klocke, Daniel, additional, Kneifel, Stefan, additional, Knippertz, Peter, additional, Kuhn, Alexander, additional, van Laar, Thriza, additional, Macke, Andreas, additional, Maurer, Vera, additional, Mayer, Bernhard, additional, Meyer, Catrin I., additional, Muppa, Shravan K., additional, Neggers, Roeland A. J., additional, Orlandi, Emiliano, additional, Pantillon, Florian, additional, Pospichal, Bernhard, additional, Röber, Niklas, additional, Scheck, Leonhard, additional, Seifert, Axel, additional, Seifert, Patric, additional, Senf, Fabian, additional, Siligam, Pavan, additional, Simmer, Clemens, additional, Steinke, Sandra, additional, Stevens, Bjorn, additional, Wapler, Kathrin, additional, Weniger, Michael, additional, Wulfmeyer, Volker, additional, Zängl, Günther, additional, Zhang, Dan, additional, and Quaas, Johannes, additional

Published
2017
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48. Large eddy simulation using the general circulation model ICON

Author

Dipankar, Anurag, Stevens, Björn, Heinze, Rieke, Moseley, Christopher, Zängl, Günther, Giorgetta, Marco, and Brdar, Slavko

Subjects
model validation, Numerical weather forecasts, cloud topped boundary layer, Numerical weather prediction, Climate prediction, Atmospheric thermodynamics, Weather forecasting, Planetary boundary layers, general circulation model, Physics::Fluid Dynamics, Dewey Decimal Classification::500 | Naturwissenschaften, Physics::Atmospheric and Oceanic Physics, Dry convective boundary layer, Boundary layer flow, turbulence, Large eddy simulation, Convective boundary layers, convective boundary layer, numerical weather forecast, Cloud-topped boundary layer, Numerical weather forecasting, Boundary layers, ddc:500, global climate, Forecasting, cumulus
Abstract

ICON (ICOsahedral Nonhydrostatic) is a unified modeling system for global numerical weather prediction (NWP) and climate studies. Validation of its dynamical core against a test suite for numerical weather forecasting has been recently published by Zängl et al. (2014). In the present work, an extension of ICON is presented that enables it to perform as a large eddy simulation (LES) model. The details of the implementation of the LES turbulence scheme in ICON are explained and test cases are performed to validate it against two standard LES models. Despite the limitations that ICON inherits from being a unified modeling system, it performs well in capturing the mean flow characteristics and the turbulent statistics of two simulated flow configurations - one being a dry convective boundary layer and the other a cumulus-topped planetary boundary layer. BMBF/01LK1202E

Published
2015

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