The radiative role of ozone and water vapour in the annual temperature cycle in the tropical tropopause layer

Ming, Alison; Maycock, Amanda C.; Hitchcock, Peter B.; Haynes, P. H.

doi:10.5194/acp-17-5677-2017

Cited by 21 publications

(26 citation statements)

References 53 publications

(71 reference statements)

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“…This is broadly consistent with prior investigations of the influence of ozone in the TTL temperature cycle (Fueglistaler et al, 2011;Ming et al, 2017). This is broadly consistent with prior investigations of the influence of ozone in the TTL temperature cycle (Fueglistaler et al, 2011;Ming et al, 2017).…”

Section: Discussionsupporting

confidence: 90%

Ozone Transport‐Radiation Feedbacks in the Tropical Tropopause Layer

Charlesworth

Birner

Albers

2019

Geophysical Research Letters

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The tropical tropopause layer (TTL) temperature balance is of considerable interest for its control over the amount of water entering the stratosphere. The upwelling branch of the Brewer-Dobson circulation (BDC) directly affects these temperatures through adiabatic cooling. BDC upwelling also indirectly affects TTL temperatures through the influence of ozone transport on radiative heating. We investigate this latter feedback using a single-column radiative-convective equilibrium model coupled with a model of simplified stratospheric ozone chemistry and vertical transport. We find that BDC ozone transport is of first-order importance for TTL temperatures. Additionally, we estimate the effect of ozone transport on cold point tropopause temperature responses to changes in upwelling. We find that the feedback is responsible for approximately 20% of the response to perturbations on time scales longer than about half a year but that this contribution can be neglected for time scales shorter than about a week. Key Points:• Interactive ozone chemistry is applied in a single-column radiative-convective equilibrium model to investigate transport processes • Ozone transport by Brewer-Dobson circulation upwelling is of first-order importance for temperature structure of tropical tropopause layer • Transport-radiation feedback:increased (decreased) upwelling reduces (increases) ozone −20% of the total cooling (warming) from upwelling Correspondence to:

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Section: Discussionsupporting

confidence: 90%

Ozone Transport‐Radiation Feedbacks in the Tropical Tropopause Layer

Charlesworth

Birner

Albers

2019

Geophysical Research Letters

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“…Time period used for ERA-I andMLS is 2005-2012. radiative heating. This effect was confirmed and further studied by Fueglistaler et al [2011], and recently extended to the radiative effects of water vapor by Gilford and Solomon [2017] and Ming et al [2017]. Gettelman et al [2009] showed that T CP in chemistry climate models (CCMs) is sensitive to the ozone amount in the TTL, which likely impacts their long-term trends in T CP .…”

Section: Introductionmentioning

confidence: 69%

“…Note that the radiative feedback due to the ozone seasonal cycle is strongest in spring and fall; i.e., our comparison between January and July only partially demonstrates this feedback. The radiative feedback due to the water vapor seasonal cycle likewise maximizes during spring and fall, with essentially no effect during January and July [ Gilford and Solomon , ; Ming et al , ]. The seasonal cycles in water vapor and ozone are in large parts produced by the seasonal cycle in upwelling [ Mote et al , ; Randel et al , ], as well as horizontal [ Konopka et al , ; Ploeger et al , ] and vertical [ Glanville and Birner , ] mixing; in that sense even the remaining seasonal temperature difference in SRE is of dynamical origin, albeit indirectly.…”

Section: Ttl In Local Radiative Equilibrium?mentioning

confidence: 99%

“…Chae and Sherwood [] found that the seasonal cycle in T CP is amplified by the radiative effects of ozone; i.e., the warmer cold point during boreal summer is in part due to the higher ozone levels near the cold point and their associated radiative heating. This effect was confirmed and further studied by Fueglistaler et al [], and recently extended to the radiative effects of water vapor by Gilford and Solomon [] and Ming et al []. Gettelman et al [] showed that T CP in chemistry climate models (CCMs) is sensitive to the ozone amount in the TTL, which likely impacts their long‐term trends in T CP .…”

Section: Introductionmentioning

confidence: 99%

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On the relative importance of radiative and dynamical heating for tropical tropopause temperatures

Birner

Charlesworth

2017

JGR Atmospheres

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The tropical tropopause layer (TTL) shows a curious stratification structure: temperature continues to decrease beyond the level of main convective outflow (∼200 hPa) up to the cold point tropopause (∼100 hPa), but the TTL is more stably stratified than the upper troposphere. A cold point tropopause well separated from the level of main convective outflow has previously been shown to be consistent with the detailed radiative balance in the TTL even without dynamical effects. However, the TTL is also controlled by adiabatic cooling due to large‐scale upwelling within the Brewer‐Dobson circulation, which creates the extremely low stratospheric water vapor content via freeze drying. Here we study the role of water vapor and ozone radiative heating on the detailed temperature structure of the TTL based on idealized single‐column radiative‐convective equilibrium simulations. An atmosphere without adiabatic cooling due to upwelling results in much higher stratospheric water vapor content; the resulting altered radiative heating structure is shown to push the TTL in a regime of radiative control by water vapor. The TTL structure is furthermore shown to be strongly sensitive to the altitude where ozone sharply transitions from tropospheric to stratospheric values. Adiabatic cooling due to upwelling is found to reduce the radiative control by water vapor, resulting primarily in a negative transport‐radiation feedback. Conversely, the radiative control by ozone is enhanced due to upwelling—a positive transport‐radiation feedback. The particularly strong ozone radiative effect may explain about half of the reported spread in cold point temperatures (∼10 K) in current climate models.

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“…An additional complication for understanding the annual cycle in O 3 is the feedback between ozone and upwelling by the residual circulation (

\overset{w}{true}

*) [ Andrews et al , ]. Changes in O 3 lead to changes in heating rates that impact the upwelling and then O 3 [ Ming et al , ]. Furthermore, changes in ozone heating rates would impact

\overset{w}{true}

* indirectly through changes in wave‐induced forcing [ Ming et al , ].…”

Section: Introductionmentioning

confidence: 99%

Hemispheric differences in the annual cycle of tropical lower stratosphere transport and tracers

Tweedy¹,

Waugh²,

Stolarski

et al. 2017

JGR Atmospheres

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Transport in the tropical lower stratosphere plays a major role in determining the composition of the entire stratosphere. Previous studies that quantified the relative role of transport processes have generally assumed well‐mixed tropics and focused on tropical‐wide average characteristics. However, it has recently been shown that there is a hemispheric difference in the annual cycle of tropical lower stratosphere ozone and other tracers, with a larger amplitude in the northern tropics (NT) than in the southern tropics (ST). In this study, we examined the ability of chemistry climate models (CCMs) to reproduce the hemispheric differences in ozone (O3) and other tracers (i.e., hydrochloric acid, or HCl and nitrous oxide, or N2O), and then use the CCMs to examine the cause of these differences. Examination of CCM simulations from the CCMVal‐2 project shows that the majority of the CCMs produce the observed feature of a larger annual cycle in the NT than ST O3 and other tracers. However, only around a third of the models produce an ozone annual cycle similar to that observed. Transformed Eulerian Mean analysis of two of the CCMs shows that seasonality in vertical advection drives the seasonality in ST O3 and N2O while seasonality of horizontal mixing drives the seasonality in NT O3 and N2O, with a large increase in horizontal mixing during northern summer (associated with the Asian monsoon). Thus, latitudinal and longitudinal variations within the tropics have to be considered to fully understand the balance between transport processes in tropical lower stratosphere.

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The radiative role of ozone and water vapour in the annual temperature cycle in the tropical tropopause layer

Cited by 21 publications

References 53 publications

Ozone Transport‐Radiation Feedbacks in the Tropical Tropopause Layer

Ozone Transport‐Radiation Feedbacks in the Tropical Tropopause Layer

On the relative importance of radiative and dynamical heating for tropical tropopause temperatures

Hemispheric differences in the annual cycle of tropical lower stratosphere transport and tracers

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