Sensitivity of tropical stratospheric ozone to rotational UV variations estimated from UARS and Aura MLS observations during the declining phases of solar cycles 22 and 23

Bossay, Sébastien; Bekki, Slimane; Marchand, Marion; Poulain, Virginie; Toumi, Ralf

doi:10.1016/j.jastp.2015.05.014

Cited by 10 publications

(12 citation statements)

References 62 publications

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“…Furthermore, the overall variation of the time lag with altitude shown in Fig. 6 is similar to that found in previous studies (Hood, 1986;Brasseur et al, 1987;Brasseur, 1993;Hood and Zhou, 1998) with a negative lag above 3-4 hPa (ozone "leading" the solar flux) and a positive lag below (ozone lagging the solar flux). As mentioned in the Introduction, the negative lag in the upper stratosphere results of the influence of the temperature feedback on the ozone response through the temperature dependent chemical reactions.…”

Section: Observed and Modeled Ozone Response To The Rotational Cyclesupporting

confidence: 88%

“…However, they noticed that including the solar induced temperature changes alone was not sufficient to adequately reproduce the observed magnitude and phase lag of the ozone response and suggested that atmospheric dynamical variability -which is not simulated in 1-D models -may also have a sizeable influence (Hood, 1986;Brasseur et al, 1987). The latter issue has later been addressed with two-dimensional models which revealed better agreement with observations (Brasseur, 1993;Fleming et al, 1995;Chen et al, 1997). Fleming et al (1995) further stressed the increasing importance with height of the solar-modulated HO x chemistry on the ozone response above 45 km.…”

Section: Introductionmentioning

confidence: 89%

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Thiéblemont¹

2017

Preprint

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Section: Observed and Modeled Ozone Response To The Rotational Cyclesupporting

confidence: 88%

Section: Introductionmentioning

confidence: 89%

Reply to reviewer #3

Thiéblemont¹

2017

Preprint

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“…A statistically significant solar signature is found in tropics in both CCMs and observations but the solar signature is generally underestimated in CCMs. Note that the solar component results are found to be strongly dependent on the length of the data series (Bossay et al, 2015). For both observations and CCMs, the amount of variance explained by the aerosol forcing is very variable and strongly depends on the period covered by the time series, whether it is background (nonvolcanic) or volcanically active periods.…”

Section: Discussionmentioning

confidence: 93%

“…It is likely that only MLR analysis on time series of at least several decades can provide robust and reliable estimates of ozone column sensitivities to solar variations for monthly mean data, especially at high latitudes (see Figure 14). If daily data have been considered, a solar signal could have been extracted from much shorter time series because of an important periodicity in the solar activity, the 27-day solar rotational cycle (Rozanov et al, 2006;Fioletov, 2009;Bossay et al, 2015).…”

Section: Absolute Contributions Of External Forcings To Interannual Vmentioning

confidence: 99%

Evaluation of the inter-annual variability of stratospheric chemical composition in chemistry-climate models using ground-based multi species time series

Poulain

Bekki

Marchand

et al. 2016

Journal of Atmospheric and Solar-Terrestrial Physics

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“…It is already well established that a substantial component of stratospheric ozone variability originates from short-term and long-term quasi-periodic fluctuations in solar activity, notably the 11-year solar magnetic activity cycle (also called the Schwabe cycle) and the 27-day solar rotational cycle (also called the Carrington cycle). Numerous observational (Bossay et al, 2015;Chandra & McPeters, 1994;Dikty et al, 2010;Fioletov, 2009;Hood, 1986;Hood & Zhou, 1998;Ruzmaikin et al, 2007;Zhou et al, 1997;Zhou et al, 2000) and modeling (Austin et al, 2007;Brasseur, 1993;Gruzdev et al, 2009;Merkel et al, 2011;Rozanov et al, 2006;Sukhodolov et al, 2017;Thiéblemont et al, 2017;Williams et al, 2001) studies have demonstrated the influence of the 27-day solar rotational cycle on stratospheric ozone. The main process responsible for the stratospheric ozone response to solar variability is the solar UV-driven photolysis of molecular oxygen (O 2 ) that is the source of O 3 in the stratosphere.…”

Section: Introductionmentioning

confidence: 99%

Nighttime Mesospheric/Lower Thermospheric Tropical Ozone Response to the 27‐Day Solar Rotational Cycle: ENVISAT‐GOMOS Satellite Observations Versus HAMMONIA Idealized Chemistry‐Climate Model Simulations

et al. 2018

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Global Ozone Monitoring by Occultation of Stars (GOMOS) satellite data are analyzed to estimate the first observation‐based nighttime (22:00 median local time) ozone response to the 27‐day solar rotational cycle in the tropical mesosphere/lower thermosphere (50–110 km altitude). The ozone response to solar rotational variability is derived from linear correlation and regressions using Lyman‐α line (121.6 nm) as solar index that varies by about 10–15% over solar rotational cycles. In the lower mesosphere (50–70 km), the GOMOS ozone is found to be correlated with the solar fluctuations and exhibits a sensitivity of ~0.1 (expressed in percent change of ozone for 1% change in Lyman‐α). In the upper mesosphere/lower thermosphere (above 80 km), ozone variations become anticorrelated with solar rotational variations. In this region, the vertical profile of ozone sensitivity to the 27‐day solar cycle exhibits a maximum of 1.8 at 81 km, a minimum of 0.3 at 100 km, and a sharp increase above. Such high ozone sensitivities are observed for the first time. The observed ozone response is compared with chemistry‐climate simulations from the Hamburg model of the neutral and ionized atmosphere (HAMMONIA) that is forced with an idealized 27‐day solar spectral irradiance time series. Although observational and model results share some common features, substantial discrepancies are found. Namely, the altitude of transition from positive to negative solar ozone correlation signal in the model simulation is found about 10 km below the altitude of the observations and the amplitude of the ozone sensitivity is generally vastly underestimated by the model.

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Sensitivity of tropical stratospheric ozone to rotational UV variations estimated from UARS and Aura MLS observations during the declining phases of solar cycles 22 and 23

Cited by 10 publications

References 62 publications

Reply to reviewer #3

Reply to reviewer #3

Evaluation of the inter-annual variability of stratospheric chemical composition in chemistry-climate models using ground-based multi species time series

Nighttime Mesospheric/Lower Thermospheric Tropical Ozone Response to the 27‐Day Solar Rotational Cycle: ENVISAT‐GOMOS Satellite Observations Versus HAMMONIA Idealized Chemistry‐Climate Model Simulations

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