National Aeronautics and Space Administration
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
GMAO RESEARCH BRIEF
Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System K. Wargan & J.E. Nielsen
BACKGROUND
SUMMARY A faithful representationof polar stratospheric chemistry inmodelsand its connection with dynamical variability is essential for ourunderstandingoftheevolutionoftheozonelayerinachangingclimateand during the projected continuing decline of ozone depletingsubstances in the atmosphere.We use a new configuration of theGoddard Earth Observing System Data Assimilation System with astratosphericchemistrymodeltostudyozonedepletionintheArcticpolarstratosphereduringtheexceptionallycold(inthestratosphere)winters2015/2016and2010/2011.
April 2017
Stratospheric ozone layer shields Earth’s biosphere from harmfulultravioletradiationandgreatly impactsthethermalstructureofthestratosphere, strongly affecting the climate. A growing number ofrecent studies suggest that the full inclusion of realistic ozone inatmosphericmodel simulationsmayhelp to improveboth seasonalweatherpredictionsandclimateprojections.
https://ntrs.nasa.gov/search.jsp?R=20170004587 2020-04-18T21:15:03+00:00Z
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
2
Thebest-knownandmostseveremanifestationofthe20thcenturystratosphericozonelossistheseasonaloccurrenceofozoneholesoverAntarctica.Althoughtoalesserdegree,thesamechemicalmechanismleadstospringtimeozonedepletionovertheArctic.Themainpathwayofozonedestructioninpolarregionsinvolvesconversionofchlorinereservoirspecies,chlorinenitrate(ClONO2)andhydrogenchloride(HCl),intoactivechlorinecompounds,ClOx,fromwhichchlorineatomsarereleasedinthepresenceofsunlight.Chlorinethencatalyticallydestroysozone.TheconversiontoClOxtakesplaceonsurfacesofsmallparticlesofpolarstratosphericclouds(PSCs).Thisprocessdependsonthreeconditions:
• Thepresenceofchlorinecompoundsinthestratosphere• LowtemperatureallowingtheformationofPSCs• Isolationoftheairmasswherethereactionstakeplace
Stratosphericchlorineloadingisstillhigh,althoughitisdecliningfollowingtheimplementationoftheMontrealProtocol.Lowtemperaturesandairisolationareattainedwithinthestratosphericpolarvortex,alarge-scalecyclonicwindpatternthatformsoverthepoleduringwintertimeandlaststhroughthefirsthalfofspring.Whenthevortexisweak,itstemperatureiselevatedinhibitingPSCformationandstrongmixingdispersesozone-depletingcompoundsatthesametimereplenishingthevortexozone.Ontheotherhand,astrongvortexactsinamannersimilartoalaboratorybeakerinwhichchlorineactivationandozonedepletiontakeplacewithlittlemixingwiththemidlatitudinalozone-richairmasses.Theseverityofpolarstratosphericozonelossstronglydependsonthetemperatureandstrengthofthepolarvortex,whichexhibitsstronginterannualvariability.The2015-2016winterwasoneofthecoldestonrecordintheArcticpolarstratosphere.ThisledtohighlevelsofchlorineactivationandrapidozonedepletionuntilthefirstweekofMarch,whenthevortexbrokedownseveralweeksearlierthanusuallypreventingfurtherchemicaldestructionofozone.Thepurposeofthisworkistwofold:
• Toestimatethe2015/2016Arcticozoneloss• TotesttheGoddardEarthObservingSystem(GEOS)DataAssimilationSystem
(DAS)withfullstratosphericchemistryforfutureatmosphericreanalyses.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
3
ExperimentandResults
AnewconfigurationofGEOS-DASisusedtostudythisozoneloss.OzoneevolutioniscomputedwithSTRATCHEM,astratosphericchemistrymodulethatsimulatesover160chemicalreactionsamong34transportedand17derivedspeciesandcontainsaPSCscheme.STRATCHEMreplacestheparameterizedchemicalmodulenormallyusedinGEOS-DASexperiments,includingmultidecadalreanalyses.Theobservationsassimilatedbythesystemconsistofradiancedatafromsatellite-bornesensors,conventionalmeasurementsandozoneobservations.Thelatterareobtainedfromtwoinstruments:theMicrowaveLimbSounder(MLS)andtheOzoneMonitoringInstrument(OMI),bothonboardNASA’sEOSAurasatellite.Combiningthereal-worldstratosphericmeteorologyconstrainedbyobservationswithachemistrymodelenablestheproductionofaglobalthree-dimensionalrepresentationoftheatmosphericcompositionanditsevolutionduringaspecifiedperiodthatcanbereadilyevaluatedagainstsatellitedata.Figure1showscomparisonsofthevortex-averagedGEOSozone,HClandchlorinemonoxide(ClO)withdatafromtheMLSinstrument.Thedatashownarefromthe480-Kpotentialtemperaturesurface,whichcorrespondstoabout20kmabovetheground.TheexcellentagreementbetweenthemodeledandMLSozoneisnotsurprisingbecauseMLSozonedataareassimilatedinthisexperiment.ButthereisalsoagoodqualitativeagreementbetweentheGEOSandMLSHCl,whichisnotassimilated.TheslowerdeclineofthemodelHClconcentrationslikelyresultedfromdeficienciesintheGEOStransport.ThisconclusionissupportedbyadditionalanalysisoftheGEOSnitrousoxideindicatingthatdownwardtransportofairinsidethevortexisunderestimatedinGEOS.PreciseestimationoftransporterrorsandstrategiestoimprovethemodelperformanceareareasofactiveresearchintheGMAO.Whiletransportissuesaffecttheatmosphericcompositionandcontributetotheestimatederrorsoftheanalysis,theyalsoprovideaninsightintotheperformanceofthemodelandtheassimilationschemeandhelptomapoutfutureimprovementsofboth.Despitethisshortcoming,theClOconcentrationsfromGEOSfollowMLSverycloselyexceptinMarchwhenthemodelgeneratesahighbiasinClO,indicativeofaslightlydelayedchlorinedeactivation.Thistooislikelyaconsequenceofmodeltransporterrorsbutcanalsoberelatedtoerrorsinthechemistrymodelthatrequirefurtherinvestigation.WenotethattheuncertaintiesintheozonebehaviorinGEOSthatresultfromthesedeficiencieshavebeenestimatedandincludedaserrorbarsinthefinalanalysisinFigure3.SinceClOisdirectlyresponsibleforozonedepletion,thiscloseagreementduringmostofthewinterprovidesconfidenceinthemodelperformancewithrespecttoozoneloss.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
4
TheGEOSmodelwritesoutchemicaltendenciesforozone, i.e.ozone’srateofchangedue to chemistry alone, other processes excluded. This allows us to estimate theevolutionoftheozonelossrateandthecumulativechemicalozonechangeduringthewinter-spring.Thetimeseriesofthevortex-averagedchemicalozonetendenciesinpartsperbillionbyvolume(ppbv)perdayisshowninFigure2(bottomleftpanel)asafunctionofpotentialtemperature,aconvenientverticalcoordinateforstratosphericstudies.Here,theverticalrangeis400Kto800K,correspondingtoheightsbetweenabout16kmand30km.Thetoppanelshowsthepoletemperatureat~20kmandthefractionofthepolarvortexilluminatedbysunlight.Asthesunlitfractionreachesabout10%inmid-January,therateofchemicalozonelossacceleratestoabout20ppbv/dayandmaximizesintheendofFebruaryat40ppbv/day.Threedistinctmaximacorrespondto increases inthepoletemperatureinmid-January,thebeginningandtheendofFebruary.Thesejumpsindicateslightdynamicalshiftsofthepositionofthepolarvortexthatslidesoffthepoleexposing larger portions of its air mass to sunlight, which accelerates photochemical
Figure1.Timeseriesofvortex-averagedozone(top),HCl(middle),andClO(bottom)atthe480-Kpotentialtemperaturesurface(~20km)fromMLS(black)andGEOS(red).Ozoneisshowninpartspermillionbyvolume(ppmv)andtheotherspeciesinpartsperbillionbyvolume(ppbv).
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
5
reactions that release atomic chlorine and strongly depend on solar illumination. Thechlorine-catalyzedozonedepletionislimitedtoelevationsbelowabout26km(potentialtemperatureofabout640K).Theozone lossabovethat level isduetoreactionswithnitrogenoxidesandisreplacedbyrapidphotochemicalproductioninMarch.
Figure3showsthecumulativeozonelossduetochemistrybetween1December2015and31March2016.Themaximumlossof2.1ppmvoccurredat480K(~20km).Thiscorrespondsto66%ofthevortexozoneon1January,asignificantamount,comparedtomostArcticwinters.Thesamepanelshowsthecumulativelossduringtherecordbreakingwinter2010/2011.Notethatwhilethemaximumdepletionthenwas3.25ppmv,thecumulativelosscomputedonlyupto12March2011(theapproximatedatewhendepletionwasterminatedin2016)wasaboutthesameas2016.Thisresultindicatesthatthe2015/2016winterwaslikelyontracktomatchtheextremeozoneloss
Figure2.(top)Thepercentageofthe480-Kpolarvortexareailluminatedbysunlightasafunctionofday(1December2015to30March2016)isshowninblack.The480-Ktemperatureatthepoleisplottedinblue.(bottom)Thevortex-averageddailyozonetendenciesduetochemistryinppbvperday.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
6
seenin2011,anoutcomeprecludedonlybytheunusuallyearlybreakupofthelower-stratosphericpolarvortexaround12March2016.Theerrorbarsaroundthelosscurveareestimatedfromthedifferencesbetweensix-hourlyozoneforecastsandsatellitedatacalculatedwithinthedataassimilationsystem.
Wenow turn to the spatial distribution of the chlorine compounds and ozone in thecontext of the stratospheric dynamics. Figure 4 shows maps of the GEOS chlorinereservoirspecies,activechlorineandozoneonthe480-Kpotentialtemperaturesurface(approximately20kmabovetheEarth’ssurface)overtheNorthPoleon11Januaryatthebeginningofozonedepletionandon21March2016afterthebreakupofthepolarvortex.ThemapsaregeneratedfromtheGEOSoutput.Thetoprowshowsthesituationinthemid-winter:lowconcentrationsofchlorinenitrateandHClcombinedwithhighquantitiesofClOxwithinthepolarvortexindicatechlorineactivationbutbeforesignificantozonelosscommenceswhenalargerportionofthevortexbecomesilluminatedbysunlight.Inthebottomrow(overtwomonthslater)thereisonlyaremnantofthepolarvortexleft,chlorineisdeactivated(ClONO2haselevatedconcentrations,ClOxisnearlygone)andverylowozonevalues,theresultofearlierchemicalloss,areseeninsidethevortexremnant.Note the consistency of chemistry and dynamics in GEOS: sharp gradients of species’
Figure3.Timeintegrated(December-March)tendencyfromFigure2inppmv(black),thesamefor6December2010–30April2011(solidblue)andfor6December2010–12March2011(dashedblue).Thebarsindicateanerrorenvelopeestimatedfromassimilationofozonedata.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
7
concentrations are aligned with the edge of the polar vortex and the chemicalcomposition inside thevortex is verydifferent than in the restof thehemisphere.Ananimatedversionofthese,andsomeadditionalmapsatthe500-Kpotentialtemperaturelevelisavailableathttps://gmao.gsfc.nasa.gov/animations/O3loss_arctic_strat.php.
Finally,wecomparethe2015/2016and2010/2011ozonelosswithinadeeplayerwheremost of the polar ozone resides. Figure 5 shows the cumulative change in the vortexozoneintegratedbetween200hPaand40hPa(~12kmto22km).TheresultsareshowninDobsonunits(DU:1DUcorrespondsto2.69×1020ozonemoleculespersquaremeterwithinthespecified layer).Thecumulative losson10Marchwasabout80DU inbothwinters.Whilethe2016lossceasedquicklyafterthebreakupofthepolarvortexanddidnotexceed90DU,in2011theGEOS-estimatedlossreachedabout126DUinApril.
Figure4.MapsofmodeledClONO2(aande),HCl(bandf),ClOx(candg),andozone(dandh)onthe480-K potential temperature surface on 11 January 2016 (a-d) and 21March 2016 (e-h). The blackcontouristheedgeofthepolarvortex.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
8
Conclusion
A new configuration of the GEOS Data Assimilation System with the STRATCHEMchemistrymodelallowedustoproduceadetailedrepresentationofpolarstratosphericozone chemistry during the exceptionally cold (in the stratosphere) 2015/2016 and2010/2011winters.Thechemistrymodelsimulates theevolutionofahostofchlorinespecies consistent with the dynamics of the polar vortex. In particular, there is anexcellentagreementbetweenthevortexchlorinemonoxidefromGEOSandMLSdata.Incombinationwithdataassimilation,themodelallowedustoestimatethemagnitudeandtemporalvariationsofchlorine-catalyzedozonelosswithinthepolarvortexandestimateitserrors.Weconcludedthatthemaximumcumulativechemicalozonelossof2.1ppmvtookplaceatabout20kmabovethesurfaceandwascomparabletotherecordArcticozonedepletionof2011uptothetimeoftheearlypolarvortexbreakupinearlyMarch.In2011,thelosscontinueduntilthebeginningofApril.Theseresultsunderscorethevalueof includingafullstratosphericchemistrymodel infuture data assimilation-based atmospheric reanalyses but also help us identifydeficiencies in transportof stratosphericconstituents inGEOS,whichwillguide futureinvestigationsandmodeldevelopments.
Figure5.Cumulativevortex-averagedchemicalozonelossinthe200hPa–40hPacolumn.Black:2010/2011,red:2015/2016.OzonelossvaluesareexpressedinDobsonunits.Thedatesofthe10hPazonalmeanzonalwindreversalat60°N(6March)andthevortexbreakupat480K(12March)in2016areshownasadottedanddashedline,respectively.
GMAO RESEARCH BRIEF Quantifying chemical ozone loss in the Arctic stratosphere with GEOS-STRATCHEM Data Assimilation System
Global Modeling and Assimilation Office NASA Goddard Space Flight Center
9
Thisworkhasbeendone incollaborationwithourcolleagues in theGMAOandotherinstitutionsandwillbeincludedinapeer-reviewedpublication,Warganetal.(2017)nowinpreparation
Reference
Wargan,K.,J.E.Nielsen,G.L.Manney,M.L.Santee,N.J.Livesey,Z.D.Lawrence,S.PawsonandL.Coy,2017:ChemicalOzoneLossDuringthe2015/2016ArcticWinterinaGoddardEarthObservingSystemAssimilationExperimentwithStratosphericChemistry.SubmittedtoJ.Geophys.Res.