Your search keyword '"Tölle, Merja H."' showing total 14 results

1. Convection-permitting climate models offer more certain extreme rainfall projections

Author

Fosser, Giorgia, Gaetani, Marco, Kendon, Elizabeth J., Adinolfi, Marianna, Ban, Nikolina, Belušić, Danijel, Caillaud, Cécile, Careto, João A. M., Coppola, Erika, Demory, Marie-Estelle, de Vries, Hylke, Dobler, Andreas, Feldmann, Hendrik, Goergen, Klaus, Lenderink, Geert, Pichelli, Emanuela, Schär, Christoph, Soares, Pedro M. M., Somot, Samuel, and Tölle, Merja H.

Published

2024

2. Evaluation of the near-surface wind field over the Adriatic region: local wind characteristics in the convection-permitting model ensemble

Author

Belušić Vozila, Andreina, Belušić, Danijel, Telišman Prtenjak, Maja, Güttler, Ivan, Bastin, Sophie, Brisson, Erwan, Demory, Marie-Estelle, Dobler, Andreas, Feldmann, Hendrik, Hodnebrog, Øivind, Kartsios, Stergios, Keuler, Klaus, Lorenz, Torge, Milovac, Josipa, Pichelli, Emanuela, Raffa, Mario, Soares, Pedro M. M., Tölle, Merja H., Truhetz, Heimo, de Vries, Hylke, and Warrach-Sagi, Kirsten

Published

2024

3. Evaluation of Alpine-Mediterranean precipitation events in convection-permitting regional climate models using a set of tracking algorithms

Author

Müller, Sebastian K., Caillaud, Cécile, Chan, Steven, de Vries, Hylke, Bastin, Sophie, Berthou, Ségolène, Brisson, Erwan, Demory, Marie-Estelle, Feldmann, Hendrik, Goergen, Klaus, Kartsios, Stergios, Lind, Petter, Keuler, Klaus, Pichelli, Emanuela, Raffa, Mario, Tölle, Merja H., and Warrach-Sagi, Kirsten

Published

2023

4. The first multi-model ensemble of regional climate simulations at kilometer-scale resolution, part I: evaluation of precipitation

Author

Ban, Nikolina, Caillaud, Cécile, Coppola, Erika, Pichelli, Emanuela, Sobolowski, Stefan, Adinolfi, Marianna, Ahrens, Bodo, Alias, Antoinette, Anders, Ivonne, Bastin, Sophie, Belušić, Danijel, Berthou, Ségolène, Brisson, Erwan, Cardoso, Rita M., Chan, Steven C., Christensen, Ole Bøssing, Fernández, Jesús, Fita, Lluís, Frisius, Thomas, Gašparac, Goran, Giorgi, Filippo, Goergen, Klaus, Haugen, Jan Erik, Hodnebrog, Øivind, Kartsios, Stergios, Katragkou, Eleni, Kendon, Elizabeth J., Keuler, Klaus, Lavin-Gullon, Alvaro, Lenderink, Geert, Leutwyler, David, Lorenz, Torge, Maraun, Douglas, Mercogliano, Paola, Milovac, Josipa, Panitz, Hans-Juergen, Raffa, Mario, Remedio, Armelle Reca, Schär, Christoph, Soares, Pedro M. M, Srnec, Lidija, Steensen, Birthe Marie, Stocchi, Paolo, Tölle, Merja H., Truhetz, Heimo, Vergara-Temprado, Jesus, de Vries, Hylke, Warrach-Sagi, Kirsten, Wulfmeyer, Volker, and Zander, Mar Janne

Published

2021

5. Impact of Abrupt Land Cover Changes by Tropical Deforestation on Southeast Asian Climate and Agriculture

Author

Tölle, Merja H., Engler, Steven, and Panitz, Hans-Jürgen

Published

2017

6. Scale dependency of regional climate modeling of current and future climate extremes in Germany

Author

Tölle, Merja H., Schefczyk, Lukas, and Gutjahr, Oliver

Published

2018

7. Northwestern Mediterranean Heavy Precipitation Events in a Warmer Climate: Robust Versus Uncertain Changes With a Large Convection‐Permitting Model Ensemble.

Author

Caillaud, Cécile, Somot, Samuel, Douville, Hervé, Alias, Antoinette, Bastin, Sophie, Brienen, Susanne, Demory, Marie‐Estelle, Dobler, Andreas, Feldmann, Hendrik, Frisius, Thomas, Goergen, Klaus, Kendon, Elizabeth J., Keuler, Klaus, Lenderink, Geert, Mercogliano, Paola, Pichelli, Emanuela, Soares, Pedro M. M., Tölle, Merja H., and de Vries, Hylke

Subjects

GLOBAL warming, CLIMATE change models, ATMOSPHERIC models

Abstract

Taking advantage of a large ensemble of Convection Permitting‐Regional Climate Models on a pan‐Alpine domain and of an object‐oriented dedicated analysis, this study aims to investigate future changes in high‐impact fall Mediterranean Heavy Precipitation Events at high warming levels. We identify a robust multi‐model agreement for an increased frequency from central Italy to the northern Balkans combined with a substantial extension of the affected areas, for a dominant influence of the driving Global Climate Models for projecting changes in the frequency, and for an increase in intensity, area, volume and severity over the French Mediterranean. However, large quantitative uncertainties persist despite the use of convection‐permitting models, with no clear agreement in frequency changes over southeastern France and a large range of plausible changes in events' properties, including for the most intense events. Model diversity and international coordination are still needed to provide policy‐relevant climate information regarding precipitation extremes. Plain Language Summary: Despite growing computational resources and multiple model developments, projecting future changes in the high‐impact Mediterranean Heavy Precipitation Events remains both a numerical and scientific challenge. The present study takes advantage of the recent availability of a relatively large ensemble of high resolution Regional Climate Models (2–3 km), which represent a step change in the simulation of precipitation extremes, and of an object‐oriented approach, allowing us to track the convective precipitating systems on an hourly basis. Looking at future changes in fall Mediterranean Heavy Precipitation Events at high warming levels, we identify a robust multi‐model agreement for an increased frequency from central Italy to the northern Balkans combined with a substantial expansion of the affected areas, and an increase in intensity, area, volume and severity over the French Mediterranean. However, considerable uncertainties remain in terms of frequency over parts of the domain arising from uncertainty in changes in large scale weather patterns, and in terms of degree of intensification for the most intense events. It suggests the need for model diversity and for more coordinated high resolution climate projections with careful selection of different driving global models in order to provide policy‐relevant climate information regarding precipitation extremes. Key Points: High‐resolution ensemble and object‐oriented approach offer a unique opportunity to study changes in Mediterranean extreme precipitationRobust agreement is found for an increase in intensity, volume and severity for future French Mediterranean Heavy Precipitation EventsEven at convection‐permitting scale, considerable uncertainty remains regarding the degree of intensification of the most extreme events [ABSTRACT FROM AUTHOR]

Published

2024

8. Biogeophysical impacts of forestation in Europe: first results from the LUCAS (Land Use and Climate Across Scales) regional climate model intercomparison.

Author

Davin, Edouard L., Rechid, Diana, Breil, Marcus, Cardoso, Rita M., Coppola, Erika, Hoffmann, Peter, Jach, Lisa L., Katragkou, Eleni, de Noblet-Ducoudré, Nathalie, Radtke, Kai, Raffa, Mario, Soares, Pedro M. M., Sofiadis, Giannis, Strada, Susanna, Strandberg, Gustav, Tölle, Merja H., Warrach-Sagi, Kirsten, and Wulfmeyer, Volker

Subjects

FORESTS & forestry, LAND use, CLOUDINESS, ATMOSPHERIC models, CLIMATOLOGY, GLOBAL temperature changes

Abstract

The Land Use and Climate Across Scales Flagship Pilot Study (LUCAS FPS) is a coordinated community effort to improve the integration of land use change (LUC) in regional climate models (RCMs) and to quantify the biogeophysical effects of LUC on local to regional climate in Europe. In the first phase of LUCAS, nine RCMs are used to explore the biogeophysical impacts of re-/afforestation over Europe: two idealized experiments representing respectively a non-forested and a maximally forested Europe are compared in order to quantify spatial and temporal variations in the regional climate sensitivity to forestation. We find some robust features in the simulated response to forestation. In particular, all models indicate a year-round decrease in surface albedo, which is most pronounced in winter and spring at high latitudes. This results in a winter warming effect, with values ranging from +0.2 to +1 K on average over Scandinavia depending on models. However, there are also a number of strongly diverging responses. For instance, there is no agreement on the sign of temperature changes in summer with some RCMs predicting a widespread cooling from forestation (well below -2 K in most regions), a widespread warming (around +2 K or above in most regions) or a mixed response. A large part of the inter-model spread is attributed to the representation of land processes. In particular, differences in the partitioning of sensible and latent heat are identified as a key source of uncertainty in summer. Atmospheric processes, such as changes in incoming radiation due to cloud cover feedbacks, also influence the simulated response in most seasons. In conclusion, the multi-model approach we use here has the potential to deliver more robust and reliable information to stakeholders involved in land use planning, as compared to results based on single models. However, given the contradictory responses identified, our results also show that there are still fundamental uncertainties that need to be tackled to better anticipate the possible intended or unintended consequences of LUC on regional climates. [ABSTRACT FROM AUTHOR]

Published

2020

9. Biogeophysical impacts of forestation in Europe: First results from the LUCAS Regional Climate Model intercomparison.

Author

Davin, Edouard L., Rechid, Diana, Breil, Marcus, Cardoso, Rita M., Coppola, Erika, Hoffmann, Peter, Jach, Lisa L., Katragkou, Eleni, de Noblet-Ducoudré, Nathalie, Radtke, Kai, Raffa, Mario, Soares, Pedro M. M., Sofiadis, Giannis, Strada, Susanna, Strandberg, Gustav, Tölle, Merja H., Warrach-Sagi, Kirsten, and Wulfmeyer, Volker

Subjects

FORESTS & forestry, ATMOSPHERIC models, LAND use, LAND use planning, CLIMATE change, GLOBAL temperature changes

Abstract

The Land Use and Climate Across Scales Flagship Pilot Study (LUCAS FPS) is a coordinated community effort to improve the integration of Land Use Change (LUC) in Regional Climate Models (RCMs) and to quantify the biogeophysical effects of LUC on local to regional climate in Europe. In the first phase of LUCAS, nine RCMs are used to explore the biogeophysical impacts of re-/afforestation over Europe. Namely, two idealized experiments representing respectively a non-forested and a maximally forested Europe are compared in order to quantify spatial and temporal variations in the regional climate sensitivity to forestation. We find some robust features in the simulated response to forestation. In particular, all models indicate a year-round decrease in surface albedo, which is most pronounced in winter and spring at high latitudes. This results in a winter warming effect, which is relatively robust across models. However, there are also a number of strongly diverging responses. For instance, there is no agreement on the sign of temperature changes in summer with some RCMs predicting a widespread cooling from forestation, a widespread warming, or a mixed response. A large part of the inter-model spread is attributed to the representation of land processes. In particular, differences in the partitioning of sensible and latent heat are identified as a key source of uncertainty. In contrast, for precipitation, the representation of atmospheric processes dictates more directly the simulated response. In conclusion, the multi-model approach we use here has the potential to deliver more robust and reliable information to stakeholders involved in land use planning, as compared to results based on single models. However, given the contradictory responses identified, our results also show that there are still fundamental uncertainties that need to be tackled to better anticipate the possible intended or unintended consequences of LUC on regional climates. [ABSTRACT FROM AUTHOR]

Published

2019

10. Effects of entrainment and mixing on droplet size distributions in warm cumulus clouds.

Author

Tölle, Merja H. and Krueger, Steven K.

Subjects

*ENTRAINMENT (Physics), *NUCLEAR liquid drop model, *PARTICLE size distribution, *CUMULUS clouds, *ISOBARIC processes, *PARAMETERIZATION

Abstract

A long-standing problem in cloud physics is the broadening of the cloud droplet spectrum in warm cumulus clouds. To isolate the changes of the droplet size distribution (DSD) due to entrainment and turbulent mixing, we used the Explicit Mixing Parcel Model (EMPM). The EMPM explicitly represents spatial variability due to entrainment and turbulent mixing down to the smallest turbulence scales in a one-dimensional domain. Several thousand individual droplets evolve by condensation or evaporation according to their local environments. We used EMPM results to characterize the evolution of the DSD due to entrainment and isobaric mixing for a wide range of conditions in a 20 m domain, including variations in entrained environmental air fraction, the turbulence dissipation rate, the size of the entrained blobs, and the relative humidity of the entrained air. We found that the broadening of the DSD due to entrainment and isobaric mixing for a specific value of the entrained air relative humidity depends only on the eddy mixing time scale and the LWC after mixing. Broadening increases substantially as the evaporation time scale decreases due to decreasing relative humidity of the entrained air. Our results also show that it is possible to parameterize the effects of entrainment and mixing on the droplet number concentration. The comprehensive results obtained for one set of values of entrained air relative humidity, droplet size, and droplet concentration should be extended to other values. [ABSTRACT FROM AUTHOR]

Published

2014

11. Increasing bioenergy production on arable land: Does the regional and local climate respond? Germany as a case study.

Author

Tölle, Merja H., Gutjahr, Oliver, Busch, Gerald, and Thiele, Jan C.

Published

2014

12. A Sensitivity Assessment of COSMO-CLM to Different Land Cover Schemes in Convection-Permitting Climate Simulations over Europe.

Author

Zhang, Mingyue, Tölle, Merja H., Hartmann, Eva, Xoplaki, Elena, and Luterbacher, Jürg

Subjects

*LEAF area index, *ATMOSPHERIC circulation, *MODES of variability (Climatology), *MOMENTUM transfer, *SNOW cover, *LAND cover

Abstract

The question of how sensitive the regional and local climates are to different land cover maps and fractions is important, as land cover affects the atmospheric circulation via its influence on heat, moisture, and momentum transfer, as well as the chemical composition of the atmosphere. In this study, we used three independent land cover data sets, GlobCover 2009, GLC2000 and ESACCI-LC, as the lower boundary of the regional climate model COSMO-CLM (Consortium for Small Scale Modeling in Climate Mode, v5.0-clm15) to perform convection-permitting regional climate simulations over the large part of Europe covering the years 1999 and 2000 at a 0.0275° horizontal resolution. We studied how the sensitivity of the impacts on regional and local climates is represented by different land cover maps and fractions, especially between warm (summer) and cold (winter) seasons. We show that the simulated regional climate is sensitive to different land cover maps and fractions. The simulated temperature and observational data are generally in good agreement, though with differences between the seasons. In comparison to winter, the summer simulations are more heterogeneous across the study region. The largest deviation is found for the alpine area (−3 to +3 °C), which might be among different reasons due to different classification systems in land cover maps and orographical aspects in the COSMO-CLM model. The leaf area index and plant cover also showed different responses based on various land cover types, especially over the area with high vegetation coverage. While relating the differences of land cover fractions and the COSMO-CLM simulation results (the leaf area index, and plant coverage) respectively, the differences in land cover fractions did not necessarily lead to corresponding bias in the simulation results. We finally provide a comparative analysis of how sensitive the simulation outputs (temperature, leaf area index, plant cover) are related to different land cover maps and fractions. The different regional representations of COSMO-CLM indicate that the soil moisture, atmospheric circulation, evaporative demand, elevation, and snow cover schemes need to be considered in the regional climate simulation with a high horizontal resolution. [ABSTRACT FROM AUTHOR]

Published

2021

13. Impact of Environmental Conditions on Grass Phenology in the Regional Climate Model COSMO-CLM.

Author

Hartmann, Eva, Schulz, Jan-Peter, Seibert, Ruben, Schmidt, Marius, Zhang, Mingyue, Luterbacher, Jürg, and Tölle, Merja H.

Subjects

PLANT phenology, ATMOSPHERIC models, PHENOLOGY, LEAF area index, LAND-atmosphere interactions, WATER supply

Abstract

Feedbacks of plant phenology to the regional climate system affect fluxes of energy, water, CO2, biogenic volatile organic compounds as well as canopy conductance, surface roughness length, and are influencing the seasonality of albedo. We performed simulations with the regional climate model COSMO-CLM (CCLM) at three locations in Germany covering the period 1999 to 2015 in order to study the sensitivity of grass phenology to different environmental conditions by implementing a new phenology module. We provide new evidence that the annually-recurring standard phenology of CCLM is improved by the new calculation of leaf area index (LAI) dependent upon surface temperature, day length, and water availability. Results with the new phenology implemented in the model show a significantly higher correlation with observations than simulations with the standard phenology. The interannual variability of LAI improves the representation of vegetation in years with extremely warm winter/spring (e.g., 2007) or extremely dry summer (e.g., 2003) and shows a more realistic growth period. The effect of the newly implemented phenology on atmospheric variables is small but tends to be positive. It should be used in future applications with an extension on more plant functional types. [ABSTRACT FROM AUTHOR]

Published

2020

14. Impact of Deforestation on Land–Atmosphere Coupling Strength and Climate in Southeast Asia.

Author

Tölle, Merja H.

Abstract

Southeast Asia (SEA) is a deforestation hotspot. A thorough understanding of the accompanying biogeophysical consequences is crucial for sustainable future development of the region's ecosystem functions and society. In this study, data from ERA-Interim driven simulations conducted with the state-of-the-art regional climate model COSMO-CLM (CCLM; version 4.8.17) at 14 km horizontal resolution are analyzed over SEA for the period from 1990 to 2004, and during El Niño–Southern Oscillation (ENSO) events for November to March. A simulation with large-scale deforested land cover is compared to a simulation with no land cover change. In order to attribute the differences due to deforestation to feedback mechanisms, the coupling strength concept is applied based on Pearson correlation coefficients. The correlations were calculated based on 10-day means between the latent heat flux and maximum temperature, the latent and sensible heat flux, and the latent heat flux and planetary boundary layer height. The results show that the coupling strength between land and atmosphere increased for all correlations due to deforestation. This implies a strong impact of the land on the atmosphere after deforestation. Differences in environmental conditions due to deforestation are most effective during La Niña years. The strength of La Nina events on the region is reduced as the impact of deforestation on the atmosphere with drier and warmer conditions superimpose this effect. The correlation strength also intensified and shifted towards stronger coupling during El Niño events for both Control and Grass simulations. However, El Niño years have the potential to become even warmer and drier than during usual conditions without deforestation. This could favor an increase in the formation of tropical cyclones. Whether deforestation will lead to a permanent transition to agricultural production increases in this region cannot be concluded. Rather, the impact of deforestation will be an additional threat besides global warming in the next decades due to the increase in the occurrence of multiple extreme events. This may change the type and severity of upcoming impacts and the vulnerability and sustainability of our society. [ABSTRACT FROM AUTHOR]

Published

2020