HEPPA-II model-measurement intercomparison project: EPP indirect effects during the dynamically perturbed NH winter 2008–2009

Funke, B.; Ball, William T.; Bender, Stefan; Gardini, A.; Harvey, V. Lynn; Lambert, A.; López‐Puertas, M.; Marsh, Daniel R.; Meraner, Katharina; Nieder, Holger; Päivärinta, S.-M.; Pérot, Kristell; Randall, C. E.; Reddmann, Thomas; Rozanov, Eugene; Schmidt, Hauke; Seppälä, Annika; Sinnhuber, Miriam; Sukhodolov, Timofei; Stiller, G. P.; Tsvetkova, N. D.; Verronen, Pekka T.; Versick, Stefan; Clarmann, T. von; Walker, Kaley A.; Yushkov, V.

doi:10.5194/acp-2016-971

Cited by 20 publications

(27 citation statements)

References 79 publications

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“…The improved representation of NO descent in WACCMX+DART is related to better representation of the elevated stratopause in this simulation (e.g., Meraner et al, ). Odin Sub‐Millimeter Radiometer observations in Figure 2 of Funke et al () show that NO of 0.1 ppmv descends to almost 0.1 hPa (∼65 km). By comparison, at 0.1 hPa the WACCMX+DART NO is 0.02–0.05 ppmv.…”

Section: Resultsmentioning

confidence: 97%

“…This is clearly captured in satellite observations that show descent of nitrogen oxides (NO x = NO + NO 2 ) and carbon monoxide (CO) into the stratosphere following the SSW (Manney et al, ; Randall et al, ). The enhanced descent is generally poorly captured by constrained chemistry climate models (e.g., Funke et al, ), which can partly be attributed to inaccurate representation of the dynamics in the upper stratosphere‐mesosphere due to lack of direct constraint at these altitudes (Siskind et al, ). The ability to accurately reproduce enhanced NO x and CO descent is therefore a useful indirect method for assessing the large‐scale dynamics in the mesosphere.…”

Section: Resultsmentioning

confidence: 99%

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Analysis and Hindcast Experiments of the 2009 Sudden Stratospheric Warming in WACCMX+DART

et al. 2018

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The ability to perform data assimilation in the Whole Atmosphere Community Climate Model eXtended version (WACCMX) is implemented using the Data Assimilation Research Testbed (DART) ensemble adjustment Kalman filter. Results are presented demonstrating that WACCMX+DART analysis fields reproduce the middle and upper atmosphere variability during the 2009 major sudden stratospheric warming (SSW) event. Compared to specified dynamics WACCMX, which constrains the meteorology by nudging toward an external reanalysis, the large‐scale dynamical variability of the stratosphere, mesosphere, and lower thermosphere is improved in WACCMX+DART. This leads to WACCMX+DART better representing the downward transport of chemical species from the mesosphere into the stratosphere following the SSW. WACCMX+DART also reproduces most aspects of the observed variability in ionosphere total electron content and equatorial vertical plasma drift during the SSW. Hindcast experiments initialized on 5, 10, 15, 20, and 25 January are used to assess the middle and upper atmosphere predictability in WACCMX+DART. A SSW, along with the associated middle and upper atmosphere variability, is initially predicted in the hindcast initialized on 15 January, which is ∼10 days prior to the warming. However, it is not until the hindcast initialized on 20 January that a major SSW is forecast to occur. The hindcast experiments reveal that dominant features of the total electron content can be forecasted ∼10–20 days in advance. This demonstrates that whole atmosphere models that properly account for variability in lower atmosphere forcing can potentially extend the ionosphere‐thermosphere forecast range.

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 99%

Analysis and Hindcast Experiments of the 2009 Sudden Stratospheric Warming in WACCMX+DART

et al. 2018

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“…Global climate models (GCMs) underestimate these effects (Funke et al, ; Hendrickx et al, ; Holt et al, ; Orsolini et al, ; Randall et al, ; Sheese et al, ), and optimum performance occurs when the models are constrained by observations to mesospheric heights (Pedatella et al, ; Sassi et al, ; Siskind et al, ). Indeed, GCMs often simulate a reversal of the winter westerlies above 70–80 km that is not consistent with observations (e.g., Smith, , see their Figure 2).…”

Section: Introductionmentioning

confidence: 99%

On the Upward Extension of the Polar Vortices Into the Mesosphere

et al. 2018

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The polar vortices play a central role in vertically coupling the atmosphere from the ground to geospace by shaping the background wind field through which atmospheric waves propagate. This work extends the vertical range of previous polar vortex climatologies into the upper mesosphere. The mesospheric polar vortices are defined using the CO gradient method with Microwave Limb Sounder satellite data; the stratospheric polar vortices are defined using a stream function‐based algorithm with data from meteorological reanalyses. Strengths and weaknesses of the two vortex definitions are given, as well as recommendations for when, where, and why to use each definition. Midwinter mean vortex geometry in the mesosphere is funnel shaped in the Arctic, with a wide top and narrow bottom. The Antarctic mesospheric vortex tapers with height in early winter and broadens with height in late winter. The seasonal evolution of mesospheric vortex frequency of occurrence, size, and zonal symmetry in both hemispheres is presented. Unexpected behavior above 60 km includes late season vortex broadening in both hemispheres, especially following winters without sudden stratospheric warmings. Following extreme stratospheric disturbances the polar night jet in the mesosphere strengthens and shifts poleward, resulting in a mesospheric vortex that contracts. Overall, the mesospheric polar vortices are more similar between the two hemispheres than their stratospheric counterparts. The vortex climatology presented here serves as an observational benchmark to which the mesospheric polar vortices in high‐top climate models can be evaluated.

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“…In contrast, while the chemical lifetime of NO x in the sunlit mesosphere and lower thermosphere is typically ~18 hr, in darkness NO x can persist for months (Shimazaki, ; Solomon et al, ). This long lifetime allows auroral NO in the lower thermosphere, and mesospheric NO produced directly by MEE ionization, to be transported downward inside the polar vortex at high latitudes during winter into the stratosphere where it depletes ozone (e.g., Clilverd et al, ; Funke et al, ; Randall et al, ; Sinnhuber et al, ; Siskind et al, ).…”

Section: Introductionmentioning

confidence: 99%

Observations and Modeling of Increased Nitric Oxide in the Antarctic Polar Middle Atmosphere Associated With Geomagnetic Storm‐Driven Energetic Electron Precipitation

et al. 2018

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Nitric oxide (NO) produced in the polar middle and upper atmosphere by energetic particle precipitation depletes ozone in the mesosphere and, following vertical transport in the winter polar vortex, in the stratosphere. Medium‐energy electron (MEE) ionization by 30–1,000 keV electrons during geomagnetic storms may have a significant role in mesospheric NO production. However, questions remain about the relative importance of direct NO production by MEE at altitudes ~60–90 km versus indirect NO originating from auroral ionization above 90 km. We investigate potential drivers of NO variability in the southern‐hemisphere mesosphere and lower thermosphere during 2013–2014. Contrasting geomagnetic activity occurred during the two austral winters, with more numerous moderate storms in the 2013 winter. Ground‐based millimeter‐wave observations of NO from Halley, Antarctica, are compared with measurements by the Solar Occultation For Ice Experiment (SOFIE) spaceborne spectrometer. NO partial columns over the altitude range 65–140 km from the two observational data sets show large day‐to‐day variability and significant disagreement, with Halley values on average 49% higher than the corresponding SOFIE data. SOFIE NO number densities, zonally averaged over geomagnetic latitudes −59° to −65°, are up to 3 × 108/cm3 higher in the winter of 2013 compared to 2014. Comparisons with a new version of the Whole Atmosphere Community Climate Model, which includes detailed D‐region ion chemistry (WACCM‐SIC) and MEE ionization rates, show that the model underestimates NO in the winter lower mesosphere whereas thermospheric abundances are too high. This indicates the need to further improve and verify WACCM‐SIC with respect to MEE ionization, thermospheric NO chemistry, and vertical transport.

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HEPPA-II model-measurement intercomparison project: EPP indirect effects during the dynamically perturbed NH winter 2008–2009

Cited by 20 publications

References 79 publications

Analysis and Hindcast Experiments of the 2009 Sudden Stratospheric Warming in WACCMX+DART

Analysis and Hindcast Experiments of the 2009 Sudden Stratospheric Warming in WACCMX+DART

On the Upward Extension of the Polar Vortices Into the Mesosphere

Observations and Modeling of Increased Nitric Oxide in the Antarctic Polar Middle Atmosphere Associated With Geomagnetic Storm‐Driven Energetic Electron Precipitation

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