Your search keyword '"O. Gutjahr"' showing total 3 results

1. The ICON Earth System Model Version 1.0 1

Author

Johann Jungclaus, S J Lorenz, H Schmidt, V Brovkin, N Brüggemann, F Chegini, T Crüger, P De-Vrese, V Gayler, M A Giorgetta, O Gutjahr, H Haak, S Hagemann, M Hanke, T Ilyina, P Korn, J Kröger, L Linardakis, C Mehlmann, U Mikolajewicz, W A Müller, J E M S Nabel, D Notz, H Pohlmann, D A Putrasahan, T Raddatz, L Ramme, R Redler, C H Reick, T Riddick, T Sam, R Schneck, R Schnur, M Schupfner, J.-S Von Storch, F Wachsmann, K.-H Wieners, F Ziemen, B Stevens, J Marotzke, and M Claussen

Published

2022

2. Impact of increased resolution on long-standing biases in HighResMIP-PRIMAVERA climate models

Author

E. Moreno-Chamarro, L.-P. Caron, S. Loosveldt Tomas, J. Vegas-Regidor, O. Gutjahr, M.-P. Moine, D. Putrasahan, C. D. Roberts, M. J. Roberts, R. Senan, L. Terray, E. Tourigny, P. L. Vidale, and Barcelona Supercomputing Center

Subjects

Climatology, QE1-996.5, Enginyeria agroalimentària::Ciències de la terra i de la vida::Climatologia i meteorologia [Àrees temàtiques de la UPC], Cloud cover, Intertropical Convergence Zone, Tropics, Geology, Climate models, Increased model resolution, Gulf Stream, Atmosphere, Bias, Simulació per ordinador, Long-standing biases, Upwelling, Climate model, Precipitation, PRIMAVERA project

Abstract

We examine the influence of increased resolution on four long-standing biases using five different climate models developed within the PRIMAVERA project. The biases are the warm eastern tropical oceans, the double Intertropical Convergence Zone (ITCZ), the warm Southern Ocean, and the cold North Atlantic. Atmosphere resolution increases from ∼100–200 to ∼25–50 km, and ocean resolution increases from ∼1∘ (eddy-parametrized) to ∼0.25∘ (eddy-present). For one model, ocean resolution also reaches 1/12∘ (eddy-rich). The ensemble mean and individual fully coupled general circulation models and their atmosphere-only versions are compared with satellite observations and the ERA5 reanalysis over the period 1980–2014. The four studied biases appear in all the low-resolution coupled models to some extent, although the Southern Ocean warm bias is the least persistent across individual models. In the ensemble mean, increased resolution reduces the surface warm bias and the associated cloud cover and precipitation biases over the eastern tropical oceans, particularly over the tropical South Atlantic. Linked to this and to the improvement in the precipitation distribution over the western tropical Pacific, the double-ITCZ bias is also reduced with increased resolution. The Southern Ocean warm bias increases or remains unchanged at higher resolution, with small reductions in the regional cloud cover and net cloud radiative effect biases. The North Atlantic cold bias is also reduced at higher resolution, albeit at the expense of a new warm bias that emerges in the Labrador Sea related to excessive ocean deep mixing in the region, especially in the ORCA025 ocean model. Overall, the impact of increased resolution on the surface temperature biases is model-dependent in the coupled models. In the atmosphere-only models, increased resolution leads to very modest or no reduction in the studied biases. Thus, both the coupled and atmosphere-only models still show large biases in tropical precipitation and cloud cover, and in midlatitude zonal winds at higher resolutions, with little change in their global biases for temperature, precipitation, cloud cover, and net cloud radiative effect. Our analysis finds no clear reductions in the studied biases due to the increase in atmosphere resolution up to 25–50 km, in ocean resolution up to 0.25∘, or in both. Our study thus adds to evidence that further improved model physics, tuning, and even finer resolutions might be necessary.

Published

2021

3. Comparison of ocean vertical mixing schemes in the Max Planck Institute Earth System Model (MPI-ESM1.2)

Author

O. Gutjahr, N. Brüggemann, H. Haak, J. H. Jungclaus, D. A. Putrasahan, K. Lohmann, and J.-S. von Storch

Subjects

QE1-996.5, 010504 meteorology & atmospheric sciences, Scale (ratio), 010505 oceanography, Turbulence, 0207 environmental engineering, Geology, 02 engineering and technology, Internal wave, Dissipation, Atmospheric sciences, Thermal diffusivity, 01 natural sciences, Vertical mixing, Circulation (fluid dynamics), 13. Climate action, 14. Life underwater, Diffusion (business), 020701 environmental engineering, 0105 earth and related environmental sciences

Abstract

For the first time, we compare the effects of four different ocean vertical mixing schemes on the mean state of the ocean and atmosphere in the Max Planck Institute Earth System Model (MPI-ESM1.2). These four schemes are namely the default Pacanowski and Philander (1981) (PP) scheme, the K-profile parameterization (KPP) from the Community Vertical Mixing (CVMix) library, a recently implemented scheme based on turbulent kinetic energy (TKE), and a recently developed prognostic scheme for internal wave dissipation, energy, and mixing (IDEMIX) to replace the often assumed constant background diffusivity in the ocean interior. In this study, the IDEMIX scheme is combined with the TKE scheme (collectively called the TKE+IDEMIX scheme) to provide an energetically more consistent framework for mixing, as it does not rely on the unwanted effect of creating spurious energy for mixing. Energetic consistency can have implications on the climate. Therefore, we focus on the effects of TKE+IDEMIX on the climate mean state and compare them with the first three schemes that are commonly used in other models but are not energetically consistent. We find warmer sea surface temperatures (SSTs) in the North Atlantic and Nordic Seas using KPP or TKE(+IDEMIX), which is related to 10 % higher overflows that cause a stronger and deeper upper cell of the Atlantic meridional overturning circulation (AMOC) and thereby an enhanced northward heat transport and higher inflow of warm and saline water from the Indian Ocean into the South Atlantic. Saltier subpolar North Atlantic and Nordic Seas lead to increased deep convection and thus to the increased overflows. Due to the warmer SSTs, the extratropics of the Northern Hemisphere become warmer with TKE(+IDEMIX), weakening the meridional gradient and thus the jet stream. With KPP, the tropics and the Southern Hemisphere also become warmer without weakening the jet stream. Using an energetically more consistent scheme (TKE+IDEMIX) produces a more heterogeneous and realistic pattern of vertical eddy diffusivity, with lower diffusivities in deep and flat-bottom basins and elevated turbulence over rough topography. IDEMIX improves in particular the diffusivity in the Arctic Ocean and reduces the warm bias in the Atlantic Water layer. We conclude that although shortcomings due to model resolution determine the global-scale bias pattern, the choice of the vertical mixing scheme may play an important role for regional biases.

Published

2021