Estimates of ozone return dates from Chemistry-Climate Model Initiative simulations

Abstract. >We analyse simulations performed for the Chemistry-Climate Model Initiative (CCMI) to estimate the return dates of the stratospheric ozone layer from depletion caused by anthropogenic stratospheric chlorine and bromine. We consider a total of 155 simulations from 20 models, including a range of sensitivity studies which examine the impact of climate change on ozone recovery. For the control simulations (unconstrained by nudging towards analysed meteorology) there is a large spread (±20 DU in the global average) in the predictions of the absolute ozone column. Therefore, the model results need to be adjusted for biases against historical data. Also, the interannual variability in the model results need to be smoothed in order to provide a reasonably narrow estimate of the range of ozone return dates. Consistent with previous studies, but here for a Representative Concentration Pathway (RCP) of 6.0, these new CCMI simulations project that global total column ozone will return to 1980 values in 2049 (with a 1σ uncertainty of 2043–2055). At Southern Hemisphere mid-latitudes column ozone is projected to return to 1980 values in 2045 (2039–2050), and at Northern Hemisphere mid-latitudes in 2032 (2020–2044). In the polar regions, the return dates are 2060 (2055–2066) in the Antarctic in October and 2034 (2025–2043) in the Arctic in March. The earlier return dates in the Northern Hemisphere reflect the larger sensitivity to dynamical changes. Our estimates of return dates are later than those presented in the 2014 Ozone Assessment by approximately 5–17 years, depending on the region, with the previous best estimates often falling outside of our uncertainty range. In the tropics only around half the models predict a return of ozone to 1980 values, around 2040, while the other half do not reach the 1980 value. All models show a negative trend in tropical total column ozone towards the end of the 21st century. The CCMI models generally agree in their simulation of the time evolution of stratospheric chlorine and bromine, which are the main drivers of ozone loss and recovery. However, there are a few outliers which show that the multi-model mean results for ozone recovery are not as tightly constrained as possible. Throughout the stratosphere the spread of ozone return dates to 1980 values between models tends to correlate with the spread of the return of inorganic chlorine to 1980 values. In the upper stratosphere, greenhouse gas-induced cooling speeds up the return by about 10–20 years. In the lower stratosphere, and for the column, there is a more direct link in the timing of the return dates of ozone and chlorine, especially for the large Antarctic depletion. Comparisons of total column ozone between the models is affected by different predictions of the evolution of tropospheric ozone within the same scenario, presumably due to differing treatment of tropospheric chemistry. Therefore, for many scenarios, clear conclusions can only be drawn for stratospheric ozone columns rather than the total column. As noted by previous studies, the timing of ozone recovery is affected by the evolution of N2O and CH4. However, quantifying the effect in the simulations analysed here is limited by the few realisations available for these experiments compared to internal model variability. The large increase in N2O given in RCP 6.0 extends the ozone return globally by ∼ 15 years relative to N2O fixed at 1960 abundances, mainly because it allows tropical column ozone to be depleted. The effect in extratropical latitudes is much smaller. The large increase in CH4 given in the RCP 8.5 scenario compared to RCP 6.0 also lengthens ozone return by ∼ 15 years, again mainly through its impact in the tropics. Overall, our estimates of ozone return dates are uncertain due to both uncertainties in future scenarios, in particular those of greenhouse gases, and uncertainties in models. The scenario uncertainty is small in the short term but increases with time, and becomes large by the end of the century. There are still some model–model differences related to well-known processes which affect ozone recovery. Efforts need to continue to ensure that models used for assessment purposes accurately represent stratospheric chemistry and the prescribed scenarios of ozone-depleting substances, and only those models are used to calculate return dates. For future assessments of single forcing or combined effects of CO2, CH4, and N2O on the stratospheric column ozone return dates, this work suggests that it is more important to have multi-member (at least three) ensembles for each scenario from every established participating model, rather than a large number of individual models.

[1]  S. Dhomse,et al.  An updated version of a gap-free monthly mean zonal mean ozone database , 2018, Earth System Science Data.

[2]  Daniel C. Anderson,et al.  Stratospheric Injection of Brominated Very Short‐Lived Substances: Aircraft Observations in the Western Pacific and Representation in Global Models , 2018 .

[3]  J. Haigh,et al.  Evidence for a continuous decline in lower stratospheric ozone offsetting ozone layer recovery , 2018 .

[4]  L. Polvani,et al.  Significant Weakening of Brewer‐Dobson Circulation Trends Over the 21st Century as a Consequence of the Montreal Protocol , 2018 .

[5]  S. Strahan,et al.  Decline in Antarctic Ozone Depletion and Lower Stratospheric Chlorine Determined From Aura Microwave Limb Sounder Observations , 2018 .

[6]  R. Stolarski,et al.  Estimating uncertainties in the SBUV Version 8.6 merged profile ozone data set , 2017 .

[7]  N. Abraham,et al.  Diagnosing the radiative and chemical contributions to future changes in tropical column ozone with the UM-UKCA chemistry–climate model , 2017 .

[8]  J. Haigh,et al.  Continuous decline in lower stratospheric ozone offsets ozone layer recovery , 2017 .

[9]  S. Dhomse,et al.  Detecting recovery of the stratospheric ozone layer , 2017, Nature.

[10]  S. Dhomse,et al.  Ozone sensitivity to varying greenhouse gases and ozone-depleting substances in CCMI-1 simulations , 2017 .

[11]  Andrea Stenke,et al.  Review of the global models used within phase 1 of the Chemistry–Climate Model Initiative (CCMI) , 2017 .

[12]  D. M. Groski,et al.  Stratospheric Response to Trace Gas Perturbations : Changes in Ozone and Temperature Distributions , 2017 .

[13]  Martyn P. Chipperfield,et al.  Persistent shift of the Arctic polar vortex towards the Eurasian continent in recent decades , 2016 .

[14]  V. Aquila,et al.  The Impact of Ozone-Depleting Substances on Tropical Upwelling, as Revealed by the Absence of Lower-Stratospheric Cooling since the Late 1990s , 2016 .

[15]  S. Rumbold,et al.  The Met Office HadGEM3-ES chemistry–climate model: evaluation of stratospheric dynamics and its impact on ozone , 2016 .

[16]  E. Rozanov,et al.  The role of methane in projections of 21st century stratospheric water vapour , 2016 .

[17]  Anja Schmidt,et al.  Emergence of healing in the Antarctic ozone layer , 2016, Science.

[18]  D. Fahey,et al.  Diverse policy implications for future ozone and surface UV in a changing climate , 2016 .

[19]  J. Lamarque,et al.  Stratospheric ozone chemistry feedbacks are not critical for the determination of climate sensitivity in CESM1(WACCM) , 2016 .

[20]  P. Braesicke,et al.  Future Arctic ozone recovery: the importance of chemistry and dynamics , 2016 .

[21]  R. Salawitch,et al.  The changing ozone depletion potential of N2O in a future climate , 2015 .

[22]  S. Dhomse,et al.  Quantifying the ozone and ultraviolet benefits already achieved by the Montreal Protocol , 2015, Nature Communications.

[23]  R. Ruhnke,et al.  Chemistry–Climate Interactions of Stratospheric and Mesospheric Ozone in EMAC Long-Term Simulations with Different Boundary Conditions for CO2, CH4, N2O, and ODS , 2015 .

[24]  Stanley P. Sander,et al.  NASA Data Evaluation: Chemical Kinetics and Photochemical Data for Use in Atmospheric Studies , 2014 .

[25]  P. Braesicke,et al.  Correction to “Impacts of climate change, ozone recovery, and increasing methane on surface ozone and the tropospheric oxidizing capacity” , 2014 .

[26]  S. Dhomse,et al.  Stratospheric ozone depletion from future nitrous oxide increases , 2013 .

[27]  S. Dhomse,et al.  Climate impact of stratospheric ozone recovery , 2013 .

[28]  P. J. Young,et al.  Long‐term ozone changes and associated climate impacts in CMIP5 simulations , 2013 .

[29]  Long-term changes in tropospheric and stratospheric ozone and associated climate impacts in CMIP5 simulations , 2013 .

[30]  Veronika Eyring,et al.  Overview of IGAC/SPARC Chemistry-Climate Model Initiative (CCMI) Community Simulations in Support of Upcoming Ozone and Climate Assessments , 2013 .

[31]  E. Rozanov,et al.  The sensitivity of stratospheric ozone changes through the 21st century to N 2 O and CH 4 , 2012 .

[32]  P. Young,et al.  A vertically resolved, global, gap-free ozone database for assessing or constraining global climate model simulations , 2012 .

[33]  R. Stolarski,et al.  A model study of the impact of source gas changes on the stratosphere for 1850–2100 , 2011 .

[34]  M. Kainuma,et al.  An emission pathway for stabilization at 6 Wm−2 radiative forcing , 2011 .

[35]  K. Calvin,et al.  The RCP greenhouse gas concentrations and their extensions from 1765 to 2300 , 2011 .

[36]  Veronika Eyring,et al.  Multimodel assessment of the factors driving stratospheric ozone evolution over the 21st century , 2010 .

[37]  Veronika Eyring,et al.  Chemistry-Climate Model Simulations of Twenty- First Century Stratospheric Climate and Circulation Changes , 2010 .

[38]  Veronika Eyring,et al.  Multi-model assessment of stratospheric ozone return dates and ozone recovery in CCMVal-2 models , 2010 .

[39]  T. Shepherd,et al.  Separating the dynamical effects of climate change and ozone depletion. Part I: Southern Hemisphere stratosphere , 2010 .

[40]  David S. Lee,et al.  Historical (1850–2000) gridded anthropogenic and biomass burning emissions of reactive gases and aerosols: methodology and application , 2010 .

[41]  Veronika Eyring,et al.  Sensitivity of 21st century stratospheric ozone to greenhouse gas scenarios , 2010 .

[42]  Luke D. Oman,et al.  Mechanisms and feedback causing changes in upper stratospheric ozone in the 21st century , 2010 .

[43]  D. Stephenson,et al.  Estimates of past and future ozone trends from multimodel simulations using a flexible smoothing spline methodology , 2010 .

[44]  S. Dhomse,et al.  Decline and recovery of total column ozone using a multimodel time series analysis , 2010 .

[45]  Veronika Eyring,et al.  Review of the formulation of present-generation stratospheric chemistry-climate models and associated external forcings , 2010 .

[46]  P. Bernath,et al.  Global OZone Chemistry And Related trace gas Data records for the Stratosphere (GOZCARDS) , 2015 .

[47]  Nadine Unger,et al.  Improved Attribution of Climate Forcing to Emissions , 2009, Science.

[48]  A. Ravishankara,et al.  Nitrous Oxide (N2O): The Dominant Ozone-Depleting Substance Emitted in the 21st Century , 2009, Science.

[49]  L. Oman,et al.  Impacts of climate change on stratospheric ozone recovery , 2009 .

[50]  V. Eyring,et al.  Quantitative performance metrics for stratospheric-resolving chemistry-climate models , 2008 .

[51]  R. Garcia,et al.  Acceleration of the Brewer–Dobson Circulation due to Increases in Greenhouse Gases , 2008 .

[52]  R. Stolarski,et al.  Relationship of loss, mean age of air and the distribution of CFCs to stratospheric circulation and implications for atmospheric lifetimes , 2008 .

[53]  T. Shepherd,et al.  Overview of the New CCMVal reference and sensitivity simulations in support of upcoming ozone and climate assessments and the planned SPARC CCMVal report , 2008 .

[54]  R. Stolarski,et al.  Stratospheric ozone in the post-CFC era , 2008 .

[55]  M. Schoeberl,et al.  Response of stratospheric circulation and stratosphere‐troposphere exchange to changing sea surface temperatures , 2007 .

[56]  C. Brühl,et al.  Multimodel projections of stratospheric ozone in the 21st century , 2007 .

[57]  Theodore G. Shepherd,et al.  On the attribution of stratospheric ozone and temperature changes to changes in ozone-depleting substances and well-mixed greenhouse gases , 2007 .

[58]  S. Solomon,et al.  Indirect radiative forcing of the ozone layer during the 21st century , 2007 .

[59]  J. Austin,et al.  Ensemble simulations of the decline and recovery of stratospheric ozone , 2006 .

[60]  Adam A. Scaife,et al.  Simulations of anthropogenic change in the strength of the Brewer–Dobson circulation , 2006 .

[61]  Peter H. Siegel,et al.  The Earth observing system microwave limb sounder (EOS MLS) on the aura Satellite , 2006, IEEE Transactions on Geoscience and Remote Sensing.

[62]  Dennis L. Hartmann,et al.  Changes in the strength of the Brewer‐Dobson circulation in a simple AGCM , 2005 .

[63]  P. Siegmund,et al.  A Simulation of the Separate Climate Effects of Middle-Atmospheric and Tropospheric CO2 Doubling , 2004 .

[64]  J. Austin,et al.  Coupled chemistry–climate model simulations for the period 1980 to 2020: Ozone depletion and the start of ozone recovery , 2003 .

[65]  M. Chipperfield,et al.  Comment on: Stratospheric Ozone Depletion at northern mid‐latitudes in the 21st century: The importance of future concentrations of greenhouse gases nitrous oxide and methane , 2003 .

[66]  A. Douglass,et al.  The Impact of Increasing Carbon Dioxide on Ozone Recovery , 2002 .

[67]  P. Vohralik,et al.  Stratospheric ozone depletion at northern mid latitudes in the 21st century: The importance of future concentrations of greenhouse gases nitrous oxide and methane , 2002 .

[68]  M. Déqué,et al.  Simulation des changements climatiques au cours du XXIe siècle incluant l'ozone stratosphérique , 2002 .

[69]  J. Lerner,et al.  Changes of tracer distributions in the doubled CO2 climate , 2001 .

[70]  Adam A. Scaife,et al.  Removal of chlorofluorocarbons by increased mass exchange between the stratosphere and troposphere in a changing climate , 2001, Nature.

[71]  Stratospheric Ozone Stratospheric Ozone , 1999 .

[72]  P. Vohralik,et al.  Heterogeneous BrONO2 hydrolysis: Effect on NO2 columns and ozone at high latitudes in summer , 1997 .

[73]  R. Prinn,et al.  Ozone response to a CO2 doubling: Results from a stratospheric circulation model with heterogeneous chemistry , 1992 .

[74]  David Rind,et al.  Climate change and the middle atmosphere. I - The doubled CO2 climate , 1990 .

[75]  G. Brasseur,et al.  Stratospheric Response to Trace Gas Perturbations: Changes in Ozone and Temperature Distributions , 1988, Science.

[76]  R. Garcia,et al.  The role of molecular hydrogen and methane oxidation in the water vapour budget of the stratosphere , 1988 .

[77]  J. Haigh,et al.  Ozone perturbation experiments in a two‐dimensional circulation model , 1982 .

[78]  J. D. Mahlman,et al.  Stratospheric Sensitivity to Perturbations in Ozone and Carbon Dioxide: Radiative and Dynamical Response. , 1980 .

[79]  J. Haigh,et al.  A two-dimensional calculation including atmospheric carbon dioxide and stratospheric ozone , 1979, Nature.

[80]  P. Crutzen The influence of nitrogen oxides on the atmospheric ozone content , 1970 .

[81]  A. J. Haagen-Smit The Air Pollution Problem in Los Angeles , 1950 .

[82]  A. W. Brewer Evidence for a world circulation provided by the measurements of helium and water vapour distribution in the stratosphere , 1949 .