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  • 1
    Book
    Book
    Stratospheric climate and variability from a general circulation model and observations; 1: Results for the December-February season. - (... ; 148) (1994)
    Hamburg : Max-Planck-Institut für Meteorologie
    Associated volumes
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    In: 1
    Type of Medium: Book
    Series Statement: Report / Max-Planck-Institut für Meteorologie 148
    Language: English
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  • 2
    Book
    Book
    Stratospheric climate and variability from a general circulation model and observations; 2: Results for the March-May, June-August and September-November. - (... ; 164) (1995)
    Hamburg : Max-Planck-Institut für Meteorologie
    Associated volumes
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    In: 2
    Type of Medium: Book
    Series Statement: Report / Max-Planck-Institut für Meteorologie 164
    Language: English
    Note: Literaturverz. S. 27 - 29
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  • 3
    Book
    Book
    Stratospheric climate and variability from a general circulation model and observations (1994)
    Hamburg : Max-Planck-Institut für Meteorologie
    Details Availability
    Keywords: climate ; climatic change ; stratosphere ; circulation model ; Forschungsbericht
    Type of Medium: Book
    Series Statement: Report / Max-Planck-Institut für Meteorologie ...
    Language: English
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  • 4
    Book
    Book
    The effect of varying the source spectrum of a gravity wave parameterization in a middle atmosphere general circulation model (1998)
    Hamburg : Max-Planck-Inst. für Meteorologie
    Details Availability
    Keywords: Report ; Forschungsbericht
    Type of Medium: Book
    Pages: 40 S , graph. Darst , 30 cm
    Series Statement: Report / Max-Planck-Institut für Meteorologie No. 252
    Language: English
    Note: Literaturverz. S. 20 - 23
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  • 5
    Electronic Resource
    Electronic Resource
    Stratospheric climate and variability from a general circulation model and observations (1996)
    Springer
    Climate dynamics 12 (1996), S. 615-639 
    Details
    ISSN: 1432-0894
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences , Physics
    Notes: Abstract The climate and natural variability of the large-scale stratospheric circulation simulated by a newly developed general circulation model are evaluated against available global observations. The simulation consisted of a 30-year annual cycle integration performed with a comprehensive model of the troposphere and stratosphere. The observations consisted of a 15-year dataset from global operational analyses of the troposphere and stratosphere. The model evaluation concentrates on the simulation of the evolution of the extratropical stratospheric circulation in both hemispheres. The December–February climatology of the observed zonal mean winter circulation is found to be reasonably well captured by the model, although in the Northern Hemisphere upper stratosphere the simulated westerly winds are systematically stronger and a cold bias is apparent in the polar stratosphere. This Northern Hemisphere stratospheric cold bias virtually disappears during spring (March–May), consistent with a realistic simulation of the spring weakening of the mean westerly winds in the model. A considerable amount of monthly interannual variability is also found in the simulation in the Northern Hemisphere in late winter and early spring. The simulated interannual variability is predominantly caused by polar warmings of the stratosphere, in agreement with observations. The breakdown of the Northern Hemisphere stratospheric polar vortex appears therefore to occur in a realistic way in the model. However, in early winter the model severely underestimates the interannual variability, especially in the upper troposphere. The Southern Hemisphere winter (June–August) zonal mean temperature is systematically colder in the model, and the simulated winds are somewhat too strong in the upper stratosphere. Contrary to the results for the Northern Hemisphere spring, this model cold bias worsens during the Southern Hemisphere spring (September–November). Significant discrepancies between the model results and the observations are therefore found during the breakdown of the Southern Hemisphere polar vortex. For instance, the simulated Southern Hemisphere stratosphere westerly jet continuously decreases in intensity more or less in situ from June to November, while the observed stratospheric jet moves downward and poleward.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00216270
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  • 6
    Electronic Resource
    Electronic Resource
    Stratospheric climate and variability from a general circulation model and observations (1996)
    Springer
    Climate dynamics 12 (1996), S. 615-639 
    Details
    ISSN: 1432-0894
    Source: Springer Online Journal Archives 1860-2000
    Topics: Geosciences , Physics
    Notes: Abstract. The climate and natural variability of the large-scale stratospheric circulation simulated by a newly developed general circulation model are evaluated against available global observations. The simulation consisted of a 30-year annual cycle integration performed with a comprehensive model of the troposphere and stratosphere. The observations consisted of a 15-year dataset from global operational analyses of the troposphere and stratosphere. The model evaluation concentrates on the simulation of the evolution of the extratropical stratospheric circulation in both hemispheres. The December–February climatology of the observed zonal mean winter circulation is found to be reasonably well captured by the model, although in the Northern Hemisphere upper stratosphere the simulated westerly winds are systematically stronger and a cold bias is apparent in the polar stratosphere. This Northern Hemisphere stratospheric cold bias virtually disappears during spring (March–May), consistent with a realistic simulation of the spring weakening of the mean westerly winds in the model. A considerable amount of monthly interannual variability is also found in the simulation in the Northern Hemisphere in late winter and early spring. The simulated interannual variability is predominantly caused by polar warmings of the stratosphere, in agreement with observations. The breakdown of the Northern Hemisphere stratospheric polar vortex appears therefore to occur in a realistic way in the model. However, in early winter the model severely underestimates the interannual variability, especially in the upper troposphere. The Southern Hemisphere winter (June–August) zonal mean temperature is systematically colder in the model, and the simulated winds are somewhat too strong in the upper stratosphere. Contrary to the results for the Northern Hemisphere spring, this model cold bias worsens during the Southern Hemisphere spring (September–November). Significant discrepancies between the model results and the observations are therefore found during the breakdown of the Southern Hemisphere polar vortex. For instance, the simulated Southern Hemisphere stratospheric westerly jet continuously decreases in intensity more or less in situ from June to November, while the observed stratospheric jet moves downward and poleward.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00216270
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    Paper (German National Licenses)
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  • 7
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    On the lack of stratospheric dynamical variability in low-top versions of the CMIP5 models (2012)
    AGU (American Geophysical Union)
    In:  Journal of Geophysical Research: Atmospheres, 118 (6). pp. 2494-2505.
    Details
    Publication Date: 2018-02-06
    Description: We describe the main differences in simulations of stratospheric climate and variability by models within the fifth Coupled Model Intercomparison Project (CMIP5) that have a model top above the stratopause and relatively fine stratospheric vertical resolution (high-top), and those that have a model top below the stratopause (low-top). Although the simulation of mean stratospheric climate by the two model ensembles is similar, the low-top model ensemble has very weak stratospheric variability on daily and interannual time scales. The frequency of major sudden stratospheric warming events is strongly underestimated by the low-top models with less than half the frequency of events observed in the reanalysis data and high-top models. The lack of stratospheric variability in the low-top models affects their stratosphere-troposphere coupling, resulting in short-lived anomalies in the Northern Annular Mode, which do not produce long-lasting tropospheric impacts, as seen in observations. The lack of stratospheric variability, however, does not appear to have any impact on the ability of the low-top models to reproduce past stratospheric temperature trends. We find little improvement in the simulation of decadal variability for the high-top models compared to the low-top, which is likely related to the fact that neither ensemble produces a realistic dynamical response to volcanic eruptions
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1002/jgrd.50125
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 8
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    Global response to solar radiation absorbed by phytoplankton in a coupled climate model (2012)
    Springer
    In:  Climate Dynamics, 39 (7-8). pp. 1951-1968.
    Details
    Publication Date: 2019-09-23
    Description: The global climate response to solar radiation absorbed by phytoplankton is investigated by performing multi-century simulations with a coupled ocean-atmosphere-biogeochemistry model. The absorption of solar radiation by phytoplankton increases radiative heating in the near-surface ocean and raises sea surface temperature (SST) by overall similar to 0.5A degrees C. The resulting increase in evaporation enhances specific atmospheric humidity by 2-5%, thereby increasing the Earth's greenhouse effect and the atmospheric temperatures. The Hadley Cell exhibits a weakening and poleward expansion, therefore reducing cloudiness at subtropical-middle latitudes and increasing it at tropical latitudes except near the Equator. Higher SST at polar latitudes reduces sea ice cover and albedo, thereby increasing the high-latitude ocean absorption of solar radiation. Changes in the atmospheric baroclinicity cause a poleward intensification of mid-latitude westerly winds in both hemispheres. As a result, the North Atlantic Ocean meridional overturning circulation extends more northward, and the equatorward Ekman transport is enhanced in the Southern Ocean. The combination of local and dynamical processes decreases upper-ocean heat content in the Tropics and in the subpolar Southern Ocean, and increases it at middle latitudes. This study highlights the relevance of coupled ocean-atmosphere processes in the global climate response to phytoplankton solar absorption. Given that simulated impacts of phytoplankton on physical climate are within the range of natural climate variability, this study suggests the importance of phytoplankton as an internal constituent of the Earth's climate and its potential role in participating in its long-term climate adjustments.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1007/s00382-012-1300-9
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 9
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    Troposphere–stratosphere response to large-scale North Atlantic Ocean variability in an atmosphere/ocean coupled model (2016)
    Springer
    In:  Climate Dynamics, 46 (5-6). pp. 1397-1415.
    Details
    Publication Date: 2019-02-01
    Description: The instrumental records indicate that the basin-wide wintertime North Atlantic warm conditions are accompanied by a pattern resembling negative North Atlantic oscillation (NAO), and cold conditions with pattern resembling the positive NAO. This relation is well reproduced in a control simulation by the stratosphere resolving atmosphere–ocean coupled Max-Planck-Institute Earth System Model (MPI-ESM). Further analyses of the MPI-ESM model simulation shows that the large-scale warm North Atlantic conditions are associated with a stratospheric precursory signal that propagates down into the troposphere, preceding the wintertime negative NAO. Additional experiments using only the atmospheric component of MPI-ESM (ECHAM6) indicate that these stratospheric and tropospheric changes are forced by the warm North Atlantic conditions. The basin-wide warming excites a wave-induced stratospheric vortex weakening, stratosphere/troposphere coupling and a high-latitude tropospheric warming. The induced high-latitude tropospheric warming is associated with reduction of the growth rate of low-level baroclinic waves over the North Atlantic region, contributing to the negative NAO pattern. For the cold North Atlantic conditions, the strengthening of the westerlies in the coupled model is confined to the troposphere and lower stratosphere. Comparing the coupled and uncoupled model shows that in the cold phase the tropospheric changes seen in the coupled model are not well reproduced by the standalone atmospheric configuration. Our experiments provide further evidence that North Atlantic Ocean variability (NAV) impacts the coupled stratosphere/troposphere system. As NAV has been shown to be predictable on seasonal-to-decadal timescales, these results have important implications for the predictability of the extra-tropical atmospheric circulation on these time-scales
    Type: Article , PeerReviewed , info:eu-repo/semantics/article
    Format: text
    DOI: 10.1007/s00382-015-2654-6
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    OceanRep: Article in a Scientific Journal - peer-reviewed
  • 10
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    Stratosphere key for wintertime atmospheric response to warm Atlantic decadal conditions (2014)
    Springer
    In:  Climate Dynamics, 42 (3/4). pp. 649-663.
    Details
    Publication Date: 2016-09-13
    Description: There is evidence that the observed changes in winter North Atlantic Oscillation (NAO) drive a significant portion of Atlantic Multi Decadal Variability (AMV). However, whether the observed decadal NAO changes can be forced by the ocean is controversial. There is also evidence that artificially imposed multi-decadal stratospheric changes can impact the troposphere in winter. But the origins of such stratospheric changes are still unclear, especially in early to mid winter, where the radiative ozone-impact is negligible. Here we show, through observational analysis and atmospheric model experiments, that large-scale Atlantic warming associated with AMV drives high-latitude precursory stratospheric warming in early to mid winter that propagates downward resulting in a negative tropospheric NAO in late winter. The mechanism involves stratosphere/troposphere dynamical coupling, and can be simulated to a large extent, but only with a stratosphere resolving model (i.e., high-top). Further analysis shows that this precursory stratospheric response can be explained by the shift of the daily extremes toward more major stratospheric warming events. This shift cannot be simulated with the atmospheric (low-top) model configuration that poorly resolves the stratosphere and implements a sponge layer in upper model levels. While the potential role of the stratosphere in multi-decadal NAO and Atlantic meridional overturning circulation changes has been recognised, our results show that the stratosphere is an essential element of extra-tropical atmospheric response to ocean variability. Our findings suggest that the use of stratosphere resolving models should improve the simulation, prediction, and projection of extra-tropical climate, and lead to a better understanding of natural and anthropogenic climate change.
    Type: Article , PeerReviewed
    Format: text
    DOI: 10.1007/s00382-013-1860-3
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    OceanRep: Article in a Scientific Journal - peer-reviewed
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