Energetic particle precipitation: A major driver of the ozone budget in the Antarctic upper stratosphere

Damiani, Alessandro; Funke, B.; López‐Puertas, M.; Santee, M. L.; Cordero, Raúl R.; Watanabe, Shingo

doi:10.1002/2016gl068279

Cited by 49 publications

(64 citation statements)

References 47 publications

(77 reference statements)

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“…A clear negative downwelling signal of 5-30 % is observed in Antarctic winter 2003 from the lower mesosphere (≈ 0.3 hPa) in mid-winter to the lower stratosphere (below 10 hPa) in spring, preceded by a weaker (5-10 %) positive signal. The structure and strengths of this signal are similar to the downwelling anomalies derived from global satellite observations for the Southern Hemisphere (Fytterer et al, 2015a;Damiani et al, 2016) when comparing composites of years with high minus low geomagnetic activity, and are interpreted as particle impacts there. In the Northern Hemisphere, a similar negative downwelling signal starts in the lower mesosphere in early winter [2003][2004], but is interrupted by a strong (> 40 %) positive anomaly in late 2003 and early 2004 that is probably related to the onset of the sudden stratospheric warming.…”

Section: Comparison Of Modeled and Observed Ozone Anomaliessupporting

confidence: 64%

“…Previous studies based on observations have compared observations of ozone in situations with and without elevated amounts of NO y on the same day and in the same latitude range (Natarajan et al, 2004), the evolution of ozone in years with high energetic particle fluxes compared to years with low particle fluxes (Randall et al, 2005), and the composite difference of years with high minus years with low particle fluxes (Fytterer et al, 2015a;Damiani et al, 2016). All methods have yielded lower values of ozone in the upper stratosphere presumably related to the energetic particle precipitation; the composite method also shows negative ozone anomalies proceeding downwards from the stratopause to the mid-stratosphere during polar winter.…”

Section: Comparison Of Modeled and Observed Ozone Anomaliesmentioning

confidence: 99%

“…Lower values of ozone in the upper stratosphere are observed during winters characterized by large particle forcing or enhanced values of NO y (Natarajan et al, 2004;Randall et al, 2005), and downwelling negative ozone anomalies were observed for the first time by Fytterer et al (2015a) and Damiani et al (2016). However, quantification of the particle-induced ozone loss by observations is difficult, because (a) MIPAS observations of EPP NO x show that EPP-induced ozone loss must occur in every year, so only relative differences can be obtained from observations; (b) stratospheric ozone is quite variable anyway; and (c) a much longer time series than used by (Fytterer et al, 2015a) would be necessary to attribute the observed anomalies clearly to the particle precipitation.…”

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confidence: 98%

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NOy production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

Sinnhuber

Berger²,

Funke

et al. 2018

Atmos. Chem. Phys.

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Abstract. We analyze the impact of energetic particle precipitation on the stratospheric nitrogen budget, ozone abundances and net radiative heating using results from three global chemistry-climate models considering solar protons and geomagnetic forcing due to auroral or radiation belt electrons. Two of the models cover the atmosphere up to the lower thermosphere, the source region of auroral NO production. Geomagnetic forcing in these models is included by prescribed ionization rates. One model reaches up to about 80 km, and geomagnetic forcing is included by applying an upper boundary condition of auroral NO mixing ratios parameterized as a function of geomagnetic activity. Despite the differences in the implementation of the particle effect, the resulting modeled NOy in the upper mesosphere agrees well between all three models, demonstrating that geomagnetic forcing is represented in a consistent way either by prescribing ionization rates or by prescribing NOy at the model top.Compared with observations of stratospheric and mesospheric NOy from the Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) instrument for the years 2002–2010, the model simulations reproduce the spatial pattern and temporal evolution well. However, after strong sudden stratospheric warmings, particle-induced NOy is underestimated by both high-top models, and after the solar proton event in October 2003, NOy is overestimated by all three models. Model results indicate that the large solar proton event in October 2003 contributed about 1–2 Gmol (109 mol) NOy per hemisphere to the stratospheric NOy budget, while downwelling of auroral NOx from the upper mesosphere and lower thermosphere contributes up to 4 Gmol NOy. Accumulation over time leads to a constant particle-induced background of about 0.5–1 Gmol per hemisphere during solar minimum, and up to 2 Gmol per hemisphere during solar maximum. Related negative anomalies of ozone are predicted by the models in nearly every polar winter, ranging from 10–50 % during solar maximum to 2–10 % during solar minimum. Ozone loss continues throughout polar summer after strong solar proton events in the Southern Hemisphere and after large sudden stratospheric warmings in the Northern Hemisphere. During mid-winter, the ozone loss causes a reduction of the infrared radiative cooling, i.e., a positive change of the net radiative heating (effective warming), in agreement with analyses of geomagnetic forcing in stratospheric temperatures which show a warming in the late winter upper stratosphere. In late winter and spring, the sign of the net radiative heating change turns to negative (effective cooling). This spring-time cooling lasts well into summer and continues until the following autumn after large solar proton events in the Southern Hemisphere, and after sudden stratospheric warmings in the Northern Hemisphere.

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Section: Comparison Of Modeled and Observed Ozone Anomaliessupporting

confidence: 64%

Section: Comparison Of Modeled and Observed Ozone Anomaliesmentioning

confidence: 99%

mentioning

confidence: 98%

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NOy production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

Sinnhuber

Berger²,

Funke

et al. 2018

Atmos. Chem. Phys.

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“…This has been postulated already by Solomon et al (1982) and observed many times (Callis et al, 1996;Stratospheric ozone loss due to electron-induced NO x production in the upper mesosphere-lower thermosphere and subsequent downward transport has been postulated by model experiments many times (Solomon et al, 1982;Schmidt et al, 2006;Marsh et al, 2007;Baumgaertner et al, 2009;Reddmann et al, 2010;Semeniuk et al, 2011;Rozanov et al, 2012). However, observational evidence for EPP-induced variations of stratospheric ozone linked to geomagnetic activity, characterized by a negative anomaly moving down with time during polar winter, have been given only very recently (Fytterer et al, 2015a;Damiani et al, 2016).…”

Section: Geomagnetic Forcing (Auroral and Radiation Belt Electrons)mentioning

confidence: 92%

Solar forcing for CMIP6 (v3.2)

et al. 2017

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Abstract. This paper describes the recommended solar forcing dataset for CMIP6 and highlights changes with respect to CMIP5. The solar forcing is provided for radiative properties, namely total solar irradiance (TSI), solar spectral irradiance (SSI), and the F10.7 index as well as particle forcing, including geomagnetic indices Ap and Kp, and ionization rates to account for effects of solar protons, electrons, and galactic cosmic rays. This is the first time that a recommendation for solar-driven particle forcing has been provided for a CMIP exercise. The solar forcing datasets are provided at daily and monthly resolution separately for the CMIP6 preindustrial control, historical (1850CMIP6 preindustrial control, historical ( -2014, and future (2015-2300) simulations. For the preindustrial control simulation, both constant and time-varying solar forcing components are provided, with the latter including variability on 11-year and shorter timescales but no long-term changes. For the future, we provide a realistic scenario of what solar behavior could be, as well as an additional extreme Maunderminimum-like sensitivity scenario. This paper describes the forcing datasets and also provides detailed recommendations as to their implementation in current climate models.For the historical simulations, the TSI and SSI time series are defined as the average of two solar irradiance models that are adapted to CMIP6 needs: an empirical onePublished by Copernicus Publications on behalf of the European Geosciences Union. A new and lower TSI value is recommended: the contemporary solar-cycle average is now 1361.0 W m −2 . The slight negative trend in TSI over the three most recent solar cycles in the CMIP6 dataset leads to only a small global radiative forcing of −0.04 W m −2 . In the 200-400 nm wavelength range, which is important for ozone photochemistry, the CMIP6 solar forcing dataset shows a larger solar-cycle variability contribution to TSI than in CMIP5 (50 % compared to 35 %).We compare the climatic effects of the CMIP6 solar forcing dataset to its CMIP5 predecessor by using timeslice experiments of two chemistry-climate models and a reference radiative transfer model. The differences in the long-term mean SSI in the CMIP6 dataset, compared to CMIP5, impact on climatological stratospheric conditions (lower shortwave heating rates of −0.35 K day −1 at the stratopause), cooler stratospheric temperatures (−1.5 K in the upper stratosphere), lower ozone abundances in the lower stratosphere (−3 %), and higher ozone abundances (+1.5 % in the upper stratosphere and lower mesosphere). Between the maximum and minimum phases of the 11-year solar cycle, there is an increase in shortwave heating rates (+0.2 K day −1 at the stratopause), temperatures (∼ 1 K at the stratopause), and ozone (+2.5 % in the upper stratosphere) in the tropical upper stratosphere using the CMIP6 forcing dataset. This solar-cycle response is slightly larger, but not statistically significantly different from that for the CMIP5 forcing dataset.CMIP6 models wi...

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“…Only recently have long-term satellite observations with good temporal and spatial coverage become available. In austral polar winter EPP causes an ozone loss of about 10-15 % descending from 1 hPa in early winter to 10 hPa in late winter (Fytterer et al, 2015;Damiani et al, 2016). Extensive information on the current knowledge of energetic particle precipitation can be found in Sinnhuber et al (2012) and Mironova et al (2015).…”

Section: Introductionmentioning

confidence: 99%

Climate impact of idealized winter polar mesospheric and stratospheric ozone losses as caused by energetic particle precipitation

Meraner

Schmidt

2018

Atmos. Chem. Phys.

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Abstract. Energetic particles enter the polar atmosphere and enhance the production of nitrogen oxides and hydrogen oxides in the winter stratosphere and mesosphere. Both components are powerful ozone destroyers. Recently, it has been inferred from observations that the direct effect of energetic particle precipitation (EPP) causes significant longterm mesospheric ozone variability. Satellites observe a decrease in mesospheric ozone up to 34 % between EPP maximum and EPP minimum. Stratospheric ozone decreases due to the indirect effect of EPP by about 10-15 % observed by satellite instruments. Here, we analyze the climate impact of winter boreal idealized polar mesospheric and polar stratospheric ozone losses as caused by EPP in the coupled Max Planck Institute Earth System Model (MPI-ESM). Using radiative transfer modeling, we find that the radiative forcing of mesospheric ozone loss during polar night is small. Hence, climate effects of mesospheric ozone loss due to energetic particles seem unlikely. Stratospheric ozone loss due to energetic particles warms the winter polar stratosphere and subsequently weakens the polar vortex. However, those changes are small, and few statistically significant changes in surface climate are found.

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Energetic particle precipitation: A major driver of the ozone budget in the Antarctic upper stratosphere

Cited by 49 publications

References 47 publications

NO<sub><i>y</i></sub> production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

NO<sub><i>y</i></sub> production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

Solar forcing for CMIP6 (v3.2)

Climate impact of idealized winter polar mesospheric and stratospheric ozone losses as caused by energetic particle precipitation

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Energetic particle precipitation: A major driver of the ozone budget in the Antarctic upper stratosphere

Cited by 49 publications

References 47 publications

NO&lt;sub&gt;&lt;i&gt;y&lt;/i&gt;&lt;/sub&gt; production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

NO&lt;sub&gt;&lt;i&gt;y&lt;/i&gt;&lt;/sub&gt; production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

Solar forcing for CMIP6 (v3.2)

Climate impact of idealized winter polar mesospheric and stratospheric ozone losses as caused by energetic particle precipitation

Contact Info

Product

Resources

About

NO<sub><i>y</i></sub> production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010

NO<sub><i>y</i></sub> production, ozone loss and changes in net radiative heating due to energetic particle precipitation in 2002–2010