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100 Years of Progress in Understanding the Stratosphere and Mesosphere (2019)

Baldwin, Mark P. ; Birner, Thomas ; Brasseur, Guy ; [weitere]

American Meteorological Society

In: Meteorological Monographs. 2019; 59: 27.1-27.62. Published 2019 Jan 01. doi: 10.1175/amsmonographs-d-19-0003.1.

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Publikationsdatum: 2019-01-01

Beschreibung: The stratosphere contains ~17% of Earth’s atmospheric mass, but its existence was unknown until 1902. In the following decades our knowledge grew gradually as more observations of the stratosphere were made. In 1913 the ozone layer, which protects life from harmful ultraviolet radiation, was discovered. From ozone and water vapor observations, a first basic idea of a stratospheric general circulation was put forward. Since the 1950s our knowledge of the stratosphere and mesosphere has expanded rapidly, and the importance of this region in the climate system has become clear. With more observations, several new stratospheric phenomena have been discovered: the quasi-biennial oscillation, sudden stratospheric warmings, the Southern Hemisphere ozone hole, and surface weather impacts of stratospheric variability. None of these phenomena were anticipated by theory. Advances in theory have more often than not been prompted by unexplained phenomena seen in new stratospheric observations. From the 1960s onward, the importance of dynamical processes and the coupled stratosphere–troposphere circulation was realized. Since approximately 2000, better representations of the stratosphere—and even the mesosphere—have been included in climate and weather forecasting models. We now know that in order to produce accurate seasonal weather forecasts, and to predict long-term changes in climate and the future evolution of the ozone layer, models with a well-resolved stratosphere with realistic dynamics and chemistry are necessary.

Print ISSN: 0065-9401

Digitale ISSN: 1943-3646

Thema: Geographie , Geologie und Paläontologie , Physik

Publiziert von American Meteorological Society

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Downward Wave Coupling between the Stratosphere and Troposphere under Future Anthropogenic Climate Change (2018)

Lubis, Sandro W. ; Matthes, Katja ; Harnik, Nili ; [weitere]

American Meteorological Society

In: Journal of Climate. 2018; 31(10): 4135-4155. Published 2018 Apr 30. doi: 10.1175/jcli-d-17-0382.1.

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Publikationsdatum: 2018-04-30

Beschreibung: Downward wave coupling (DWC) is an important process that characterizes the dynamical coupling between the stratosphere and troposphere via planetary wave reflection. A recent modeling study has indicated that natural forcing factors, including sea surface temperature (SST) variability and the quasi-biennial oscillation (QBO), influence DWC and the associated surface impact in the Northern Hemisphere (NH). In light of this, the authors further investigate how DWC in the NH is affected by anthropogenic forcings, using a fully coupled chemistry–climate model CESM1(WACCM). The results indicate that the occurrence of DWC is significantly suppressed in the future, starting later in the seasonal cycle, with more events concentrated in late winter (February and March). The future decrease in DWC events is associated with enhanced wave absorption in the stratosphere due to increased greenhouse gases (GHGs), which is manifest as more absorbing types of stratospheric sudden warmings (SSWs) in early winter. This early winter condition leads to a delay in the development of the upper-stratospheric reflecting surface, resulting in a shift in the seasonal cycle of DWC toward late winter in the future. The tropospheric responses to DWC events in the future exhibit different spatial patterns, compared to those of the past. In the North Atlantic sector, DWC-induced circulation changes are characterized by a poleward shift and an eastward extension of the tropospheric jet, while in the North Pacific sector, the circulation changes are characterized by a weakening of the tropospheric jet. These responses are consistent with a change in the pattern of DWC-induced synoptic-scale eddy–mean flow interaction in the future.

Print ISSN: 0894-8755

Digitale ISSN: 1520-0442

Thema: Geographie , Geologie und Paläontologie , Physik

Publiziert von American Meteorological Society

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An Interdisciplinary Approach to the Study of Extreme Weather Events: Large-Scale Atmospheric Controls and Insights from Dynamical Systems Theory and Statistical Mechanics (2018)

Messori, Gabriele ; Caballero, Rodrigo ; Bouchet, Freddy ; [weitere]

American Meteorological Society

In: Bulletin of the American Meteorological Society. 2018; 99(5): ES81-ES85. Published 2018 May 01. doi: 10.1175/bams-d-17-0296.1.

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Publikationsdatum: 2018-05-01

Print ISSN: 0003-0007

Digitale ISSN: 1520-0477

Thema: Geographie , Physik

Publiziert von American Meteorological Society

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Wave and Jet Maintenance in Different Flow Regimes (2016)

Lachmy, Orli ; Harnik, Nili

American Meteorological Society

In: Journal of the Atmospheric Sciences. 2016; 73(6): 2465-2484. Published 2016 Jun 01. doi: 10.1175/jas-d-15-0321.1.

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Publikationsdatum: 2016-06-01

Beschreibung: The wave spectrum and zonal-mean-flow maintenance in different flow regimes of the jet stream are studied using a two-layer modified quasigeostrophic (QG) model. As the wave energy is increased by varying the model parameters, the flow transitions from a subtropical jet regime to a merged jet regime and then to an eddy-driven jet regime. The subtropical jet is maintained at the Hadley cell edge by zonal-mean advection of momentum, while eddy heat flux and eddy momentum flux convergence (EMFC) are weak and concentrated far poleward. The merged jet is narrow and persistent and is maintained by EMFC from a narrow wave spectrum, dominated by zonal wavenumber 5. The eddy-driven jet is wide and fluctuating and is maintained by EMFC from a wide wave spectrum. The wave–mean flow feedback mechanisms that maintain each regime are explained qualitatively. The regime transitions are related to transitions in the wave spectrum. An analysis of the wave energy spectrum budget and a comparison with a quasi-linear version of the model show that the balance maintaining the spectrum in the merged and subtropical jet regimes is mainly a quasi-linear balance, whereas in the eddy-driven jet regime nonlinear inverse energy cascade takes place. The amplitude and wavenumber of the dominant wave mode in the merged and subtropical jet regimes are determined by the constraint that this mode would produce the wave fluxes necessary for maintaining a mean flow that is close to neutrality. In contrast, the equilibrated mean flow in the eddy-driven jet regime is weakly unstable.

Print ISSN: 0022-4928

Digitale ISSN: 1520-0469

Thema: Geographie , Geologie und Paläontologie , Physik

Publiziert von American Meteorological Society

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Influence of the Quasi-Biennial Oscillation and Sea Surface Temperature Variability on Downward Wave Coupling in the Northern Hemisphere (2016)

Lubis, Sandro W. ; Matthes, Katja ; Omrani, Nour-Eddine ; [weitere]

American Meteorological Society

In: Journal of the Atmospheric Sciences. 2016; 73(5): 1943-1965. Published 2016 Apr 19. doi: 10.1175/jas-d-15-0072.1.

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Publikationsdatum: 2016-04-19

Beschreibung: Downward wave coupling occurs when an upward-propagating planetary wave from the troposphere decelerates the flow in the upper stratosphere and forms a downward reflecting surface that redirects waves back to the troposphere. To test this mechanism and potential factors influencing the downward wave coupling, three 145-yr sensitivity simulations with NCAR’s Community Earth System Model [CESM1(WACCM)], a state-of-the-art high-top chemistry–climate model, are analyzed. The results show that the quasi-biennial oscillation (QBO) and SST variability significantly impact downward wave coupling. Without the QBO, the occurrence of downward wave coupling is significantly suppressed. In contrast, stronger and more persistent downward wave coupling occurs when SST variability is excluded. The above influence on the occurrence of downward wave coupling is mostly due to a direct influence of the QBO and SST variability on stratospheric planetary wave source and propagation. The strengths of the tropospheric circulation and surface responses to a given downward wave coupling event, however, behave differently. The surface anomaly is significantly weaker (stronger) in the experiment with fixed SSTs (without QBO), even though the statistical signal of downward wave coupling is strongest (weakest) in this experiment. This apparent mismatch is explained by the differences in the strength of the synoptic-scale eddy–mean flow feedback and the possible contribution of SST anomalies in the North Atlantic during the downward wave coupling event. The weaker synoptic-scale eddy–mean flow feedback and the absence of the positive NAO-related SST-tripole pattern in the fixed SST experiment are consistent with a weaker tropospheric response to downward wave coupling. The results highlight the importance of synoptic-scale eddies in setting the tropospheric response to downward wave coupling.

Print ISSN: 0022-4928

Digitale ISSN: 1520-0469

Thema: Geographie , Geologie und Paläontologie , Physik

Publiziert von American Meteorological Society

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The Non-Gaussianity and Spatial Asymmetry of Temperature Extremes Relative to the Storm Track: The Role of Horizontal Advection (2017)

Garfinkel, Chaim I. ; Harnik, Nili

American Meteorological Society

In: Journal of Climate. 2017; 30(2): 445-464. Published 2017 Jan 01. doi: 10.1175/jcli-d-15-0806.1.

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Publikationsdatum: 2017-01-01

Beschreibung: The distribution of near-surface and tropospheric temperature variability in midlatitudes is distinguishable from a Gaussian in meteorological reanalysis data; consistent with this, warm extremes occur preferentially poleward of the location of cold extremes. To understand the factors that drive this non-Gaussianity, a dry general circulation model and a simple model of Lagrangian temperature advection are used to investigate the connections between dynamical processes and the occurrence of extreme temperature events near the surface. The non-Gaussianity evident in reanalysis data is evident in the dry model experiments, and the location of extremes is influenced by the location of the jet stream and storm track. The cause of this in the model can be traced back to the synoptic evolution within the storm track leading up to cold and warm extreme events: negative temperature extremes occur when an equatorward propagating high–low couplet (high to the west) strongly advects isotherms equatorward over a large meridional fetch over more than two days. Positive temperature anomalies occur when a poleward propagating low–high couplet (low to the west) advects isotherms poleward over a large meridional fetch over more than two days. The magnitude of the extremes is enhanced by the meridional movement of the systems. Overall, horizontal temperature advection by storm track systems can account for the warm/cold asymmetry in the latitudinal distribution of the temperature extremes.

Print ISSN: 0894-8755

Digitale ISSN: 1520-0442

Thema: Geographie , Geologie und Paläontologie , Physik

Publiziert von American Meteorological Society

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Atlantic-Pacific Asymmetry in Deep Water Formation (2018)

Ferreira, David ; Cessi, Paola ; Coxall, Helen K. ; [weitere]

Annual Reviews

In: Annual Review of Earth and Planetary Sciences. 2018; 46(1): 327-352. Published 2018 May 30. doi: 10.1146/annurev-earth-082517-010045.

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Publikationsdatum: 2018-05-30

Beschreibung: While the Atlantic Ocean is ventilated by high-latitude deep water formation and exhibits a pole-to-pole overturning circulation, the Pacific Ocean does not. This asymmetric global overturning pattern has persisted for the past 2–3 million years, with evidence for different ventilation modes in the deeper past. In the current climate, the Atlantic-Pacific asymmetry occurs because the Atlantic is more saline, enabling deep convection. To what extent the salinity contrast between the two basins is dominated by atmospheric processes (larger net evaporation over the Atlantic) or oceanic processes (salinity transport into the Atlantic) remains an outstanding question. Numerical simulations have provided support for both mechanisms; observations of the present climate support a strong role for atmospheric processes as well as some modulation by oceanic processes. A major avenue for future work is the quantification of the various processes at play to identify which mechanisms are primary in different climate states.

Print ISSN: 0084-6597

Digitale ISSN: 1545-4495

Thema: Geologie und Paläontologie , Physik

Publiziert von Annual Reviews

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Radiative effects of ozone waves on the Northern Hemisphere polar vortex and its modulation by the QBO (2018)

Silverman, Vered ; Harnik, Nili ; Matthes, Katja ; [weitere]

Copernicus

In: Atmospheric Chemistry and Physics. 2018; 18(9): 6637-6659. Published 2018 May 09. doi: 10.5194/acp-18-6637-2018.

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Publikationsdatum: 2018-05-09

Beschreibung: The radiative effects induced by the zonally asymmetric part of the ozone field have been shown to significantly change the temperature of the NH winter polar cap, and correspondingly the strength of the polar vortex. In this paper, we aim to understand the physical processes behind these effects using the National Center for Atmospheric Research (NCAR)'s Whole Atmosphere Community Climate Model, run with 1960s ozone-depleting substances and greenhouse gases. We find a mid-winter polar vortex influence only when considering the quasi-biennial oscillation (QBO) phases separately, since ozone waves affect the vortex in an opposite manner. Specifically, the emergence of a midlatitude QBO signal is delayed by 1–2 months when radiative ozone-wave effects are removed. The influence of ozone waves on the winter polar vortex, via their modulation of shortwave heating, is not obvious, given that shortwave heating is largest during fall, when planetary stratospheric waves are weakest. Using a novel diagnostic of wave 1 temperature amplitude tendencies and a synoptic analysis of upward planetary wave pulses, we are able to show the chain of events that lead from a direct radiative effect on weak early fall upward-propagating planetary waves to a winter polar vortex modulation. We show that an important stage of this amplification is the modulation of individual wave life cycles, which accumulate during fall and early winter, before being amplified by wave–mean flow feedbacks. We find that the evolution of these early winter upward planetary wave pulses and their induced stratospheric zonal mean flow deceleration is qualitatively different between QBO phases, providing a new mechanistic view of the extratropical QBO signal. We further show how these differences result in opposite radiative ozone-wave effects between east and west QBOs.

Print ISSN: 1680-7316

Digitale ISSN: 1680-7324

Thema: Geologie und Paläontologie

Publiziert von Copernicus im Namen von European Geosciences Union.

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How does downward planetary wave coupling affect polar stratospheric ozone in the Arctic winter stratosphere? (2017)

Lubis, Sandro W. ; Silverman, Vered ; Matthes, Katja ; [weitere]

Copernicus

In: Atmospheric Chemistry and Physics. 2017; 17(3): 2437-2458. Published 2017 Feb 15. doi: 10.5194/acp-17-2437-2017.

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Publikationsdatum: 2017-02-15

Beschreibung: It is well established that variable wintertime planetary wave forcing in the stratosphere controls the variability of Arctic stratospheric ozone through changes in the strength of the polar vortex and the residual circulation. While previous studies focused on the variations in upward wave flux entering the lower stratosphere, here the impact of downward planetary wave reflection on ozone is investigated for the first time. Utilizing the MERRA2 reanalysis and a fully coupled chemistry–climate simulation with the Community Earth System Model (CESM1(WACCM)) of the National Center for Atmospheric Research (NCAR), we find two downward wave reflection effects on ozone: (1) the direct effect in which the residual circulation is weakened during winter, reducing the typical increase of ozone due to upward planetary wave events and (2) the indirect effect in which the modification of polar temperature during winter affects the amount of ozone destruction in spring. Winter seasons dominated by downward wave reflection events (i.e., reflective winters) are characterized by lower Arctic ozone concentration, while seasons dominated by increased upward wave events (i.e., absorptive winters) are characterized by relatively higher ozone concentration. This behavior is consistent with the cumulative effects of downward and upward planetary wave events on polar stratospheric ozone via the residual circulation and the polar temperature in winter. The results establish a new perspective on dynamical processes controlling stratospheric ozone variability in the Arctic by highlighting the key role of wave reflection.

Print ISSN: 1680-7316

Digitale ISSN: 1680-7324

Thema: Geologie und Paläontologie

Publiziert von Copernicus im Namen von European Geosciences Union.

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On the violation of gradient wind balance at the top of tropical cyclones (2017)

Cohen, Yair ; Harnik, Nili ; Heifetz, Eyal ; [weitere]

American Geophysical Union

In: Geophysical Research Letters. 2017; 44(15): 8017-8026. Published 2017 Aug 12. doi: 10.1002/2017gl074552.

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Publikationsdatum: 2017-08-12

Beschreibung: The existence of physical solutions for the gradient wind balance is examined at the top of 12 simulated tropical cyclones. The pressure field at the top of these storms, which depends on the vertically integrated effect of the warm core and the near surface low, is found to violate the gradient wind balance—termed here as a state of nonbalance. Using a toy model, it is shown that slight changes in the relative location and relative widths of the warm core drastically increase the isobaric curvature at the upper level pressure maps leading to nonbalance. While idealized storms return to balance within several days, simulations of real-world tropical cyclones retain a considerable degree of nonbalance throughout the model integration. Comparing mean and maximum values of different storms shows that peak nonbalance correlates with either peak intensity or intensification, implying the possible importance of nonbalance at upper levels for the near surface winds. ©2017. American Geophysical Union. All Rights Reserved.

Print ISSN: 0094-8276

Digitale ISSN: 1944-8007

Thema: Geologie und Paläontologie , Physik

Publiziert von American Geophysical Union

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