Dynamical control of ozone transport and chemistry from satellite observations and CCMs Mark Weber 1, Ingo Wohltmann 2, Veronika Eyring 3, Markus Rex 2,

Slides:

Advertisements

Similar presentations

Arctic ozone loss 2011 John Pyle Scientific Assessment Panel National Centre for Atmospheric Science, UK & Centre for Atmospheric Science Department of.

Advertisements

Institut für Physik der Atmosphäre Institut für Physik der Atmosphäre Climate-Chemistry Interactions - User Requirements Martin Dameris DLR-Institut für.

Decadal Variation of the Holton-Tan Effect Hua Lu, Thomas Bracegirdle, Tony Phillips, Andrew Bushell DynVar/SNAP Workshops, April, 2013, Reading,

Ocean’s Role in the Stratosphere-Troposphere Interaction Yulia A. Zyulyaeva Moscow State University P.P.Shirshov Institute of Oceanology, RAS, Moscow 1/17.

Climate change in the Antarctic. Turner et al, Significant warming of the Antarctic Winter Troposphere. Science, vol 311, pp Radiosonde.

Institute for Climate and Atmospheric Science SCHOOL OF EARTH AND ENVIRONMENT 3D SLIMCAT Studies of Arctic Ozone Loss Wuhu Feng Acknowledgments: Martyn.

Understanding climate model biases in Southern Hemisphere mid-latitude variability Isla Simpson 1 Ted Shepherd 2, Peter Hitchcock 3, John Scinocca 4 (1)

Another hint for a changing stratospheric circulation after 2001 Harald Bönisch (1), Andreas Engel (1), Thomas Birner (2), Peter Hoor (3) (1)Institute.

Spring Onset in the Northern Hemisphere: A Role for the Stratosphere? Robert X. Black Brent A. McDaniel School of Earth and Atmospheric Sciences Georgia.

Antarctic Ozone “Hole” Review 2012 Craig S. Long 1 Larry Flynn 2, Bryan Johnson 3 NOAA 1-NWS/NCEP/Climate Prediction Center 2-NESDIS/STAR/Satellite Meteorology.

Observed decadal scale changes in polar ozone suggest solar influence through energetic electron precipitation Björn-Martin Sinnhuber Institute of Environmental.

By studying the case with QBO signal only, the model reproduces the previous observation that QBO signal of column ozone at equator is anti-correlated.

Chemistry and Transport in the Lower Stratosphere Wuhu Feng 1, Martyn Chipperfield 1, Howard Roscoe 2 1. Institute for Atmospheric Science, School of the.

Review of Northern Winter 2010/11

AGU 2006 Highlights Le Kuai Dec. 19, 2006 Le Kuai Dec. 19, 2006.

. Sensitivity Studies of Ozone Depletion with a 3D CTM Wuhu Feng 1, M.P. Chipperfield 1, S. Dhomse 1, L. Gunn 1, S. Davies 1, B. Monge-Sanz 1, V.L. Harvey.

Wuhu Feng and Martyn Chipperfield

Three-Dimensional Chemical Transport Model Studies of Arctic Ozone Depletion Wuhu Feng and Martyn Chipperfield School of the Earth and Environment, University.

Solar Forcing on Climate Through Stratospheric Ozone Change Le Kuai.

STRATOSPHERIC CHEMISTRY. TOPICS FOR TODAY 1.Review of stratospheric chemistry 2.Recent trends in stratospheric ozone and forcing 3.How will stratospheric.

Influence of the Brewer-Dobson Circulation on the Middle/Upper Tropospheric O 3 Abstract Lower Stratosphere Observations Models

Variability of Tropical to Extra-tropical Transport in the Lower Stratosphere Mark Olsen UMBC/GSFC Anne Douglass, Paul Newman, and Eric Nash.

The Current and Future States of the Ozone Layer Greg Bodeker Bodeker Scientific, Alexandra, New Zealand Presented at the 8 th Ozone Research Managers.

COST workshop, 12th March Assimilation of stratospheric ozone and water vapour at DARC Alan Geer, Carole Peubey, Ross Bannister, Roger Brugge, William.

I/1 Atmospheric transport and ozone chemistry Lecture SS 2006 Thursday, 14:15h (sharp)-15:45h Miriam Sinnhuber U3225 Tel

© Crown copyright Met Office The Brewer-Dobson circulation in the CMIP5 simulations Steven Hardiman and Neal Butchart (Met Office Hadley Centre) Natalia.

Dynamical perspective on the middle atmosphere research in Sweden , SRS-Meeting, Stockholm Heiner Körnich, MISU 1.

Using GPS data to study the tropical tropopause Bill Randel National Center for Atmospheric Research Boulder, Colorado “You can observe a lot by just watching”

Temperature trends in the upper troposphere/ lower stratosphere as revealed by CCMs and AOGCMs Eugene Cordero, Sium Tesfai Department of Meteorology San.

Radiative-dynamical processes modulating the vertical structure of the stratospheric polar vortex José M. P. Silvestre, José M. Castanheira, and Juan Ferreira.

Satellite Observations and Simulations of Subvortex Processing and Related Upper Troposphere / Lower Stratosphere Transport M.L. Santee, G.L. Manney, W.G.

March total ozone from GOME/SCIAMACHY –High inter-annual ozone variability during winter/spring NH –Combined effect from ozone transport and polar ozone.

SCIAMACHY long-term validation M. Weber, S. Mieruch, A. Rozanov, C. von Savigny, W. Chehade, R. Bauer, and H. Bovensmann Institut für Umweltphysik, Universität.

Recent variability of the solar spectral irradiance and its impact on climate modelling - TOSCA WG1 Workshop, May 2012, Berlin Stratospheric and tropospheric.

Seasonal variability of UTLS hydrocarbons observed from ACE and comparisons with WACCM Mijeong Park, William J. Randel, Louisa K. Emmons, and Douglas E.

Long-Term Changes in Northern and Southern Annular Modes Part I: Observations Christopher L. Castro AT 750.

Strengthening of Brewer- Dobson circulation since 1979 seen from observed lower- stratospheric temperatures Qiang Fu Department of Atmospheric Sciences.

Past and Future Changes in Southern Hemisphere Tropospheric Circulation and the Impact of Stratospheric Chemistry-Climate Coupling Collaborators: Steven.

Sensitivity of Antarctic climate to the distribution of ozone depletion Nathan Gillett, University of East Anglia Sarah Keeley, University of East Anglia.

Objective Data  The outlined square marks the area of the study arranged in most cases in a coarse 24X24 grid.  Data from the NASA Langley Research Center.

Figure (a-c). Latitude-height distribution of monthly mean ozone flux for the months of (a) January, (b) April and (c) July averaged over years 2000 to.

Understanding the Observed Ozone and Thermal Response To 11-Year Solar Variability Lon Hood Lunar and Planetary Laboratory University of Arizona Tucson,

How do Long-Term Changes in the Stratosphere Affect the Troposphere?

Ko pplung von Dy namik und A tmosphärischer C hemie in der S tratosphäre H 2 O in models and observations Coupling of dynamics and atmospheric chemistry.

Dynamical Control on Decadal Ozone Change S. Dhomse 1, M. Weber 1, I. Wohltmann 2, M. Rex 2, V. Eyring 3, M. Dameris 3, and J.P. Burrows 1 (1)Institute.

Acoustic-gravity wave monitoring for global atmospheric studies Elisabeth Blanc 1 Alexis Le Pichon 1 Lars Ceranna 2 Thomas Farges 1 2- BGR / B3.11, Hannover,

1 Longitudinally-dependent ozone recovery in the Antarctic polar vortex revealed by satellite-onboard ILAS-II observation in 2003 Kaoru Sato Department.

Camp et al. (2003) illustrated that two leading modes of tropical total ozone variability exhibit structrures of the QBO and the solar cycle. Figure (1)

NASA/GSFC Tropospheric Ozone Residual M. Schoeberl NASA/GSFC M. Schoeberl NASA/GSFC.

IVb/1 IV. Stratospheric ozone chemistry 1.Basic concepts of atmospheric chemistry 2.Ozone chemistry and ozone distribution 3.Sources and distribution of.

Dynamical balances and tropical stratospheric upwelling Bill Randel and Rolando Garcia NCAR Thanks to: Qiang Fu, Andrew Gettelman, Rei Ueyama, Mike Wallace,

I/1 Atmospheric transport and ozone chemistry Lecture SS 2008 Mark Weber S4350 Tel Lecture material of today:

The dynamical signal in stratospheric temperatures from satellites

Dynamical Influence on Inter-annual and Decadal Ozone Change Sandip Dhomse, Mark Weber,

1 Ozone „Recovery“ in a Changing Climate M. Weber Universität Bremen FB1, Institut für Umweltphysik (iup)

UTLS Chemical Structure, ExTL Summary of the talks –Data sets –Coordinates –Thickness of the ExTL (tracers based) Outstanding questions Discussion.

S5P tropical tropospheric ozone product based on convective cloud differential method Klaus-Peter Heue, Pieter Valks, Diego Loyola, Deutsches Zentrum für.

The impact of solar variability and Quasibiennial Oscillation on climate simulations Fabrizio Sassi (ESSL/CGD) with: Dan Marsh and Rolando Garcia (ESSL/ACD),

slide 1 Polar Ozone: Past and present Chapter 4 of WMO 2006 Ozone Assessment Summary Part 1 Polar stratospheric observations update Part 2 Progress.

Links between ozone and climate 9 th ORM Geneva, 14 May 2014 SAP Co-chairs Ayité-Lô Ajavon (Togo) Paul Newman (USA) John Pyle (UK) A.R. Ravishankara (USA)

Dynamical control of ozone transport and chemistry from satellite observations and coupled chemistry climate models Mark Weber 1, Sandip Dhomse 1, Ingo.

The origin of stratospheric ozone in sensitivity studies with EMAC-FUB EGU – European Geosciences Union General Assembly 2011 Vienna S. Meul 1), S. Oberländer.

Multivariate Time Series Analysis Charles D. Camp MSRI July 18, 2008.

1 Can variations in the tropical convection and circulation play a role in the variability of the Antarctic ozone? Leila M. V. Carvalho 1,2 and Charles.

Daily Tropospheric Ozone Residual from OMI-MLS

Static Stability in the Global UTLS Observations of Long-term Mean Structure and Variability using GPS Radio Occultation Data Kevin M. Grise David W.

Atmospheric transport and ozone chemistry

Matt Tully Bureau of Meteorology Quadrennial Ozone Symposium

Why Should We Care About the Stratosphere?

ExUTLS dynamics and global observations

Presentation transcript:

Dynamical control of ozone transport and chemistry from satellite observations and CCMs Mark Weber 1, Ingo Wohltmann 2, Veronika Eyring 3, Markus Rex 2, Sandip Dhomse 1, Folkard Wittrock 1, and Martin Dameris 3 (1)Institute of Environmental Physics, University Bremen, Bremen (2)Alfred-Wegner Institute for Polar and Marine Research, Potsdam (3)Institute of Atmospheric Physics, DLR Oberpfaffenhofen  Visit also Poster 4a-4 Wohltmann et al. Workshop Process-oriented Validation of GCMs, Garmisch-Partenkrichen, Nov 2003

Overview Diagnostics: Planetary wave driving and total ozone (OClO) Data sources: GOME (O3 and OClO), TOMS, TOMS-SBUV merged dataset, sondes Met Analyses: ERA40, NCEP, UKMO Topics:  Planetary wave driving and ozone/temperature (introduction)  Tropospheric forcing and winter ozone gain  Dynamical control of summer ozone  Chlorine activation/chemical ozone loss (polar vortex)

Annual cycle in total ozone

Interannual variability Winter/spring ozone Photochem. summer decay

GOME r=  0.74 Tropics -dO 3 /dt [DU/month] Ozone tendency in tropics and high latitudes after Fusco & Salby, 1999, Randel et al. 2002

K Temperature and zonal winds Cold tropical lowermost stratosphere/tropopause cold polar vortex Strong polar jet Link between T variability in tropics to planetary wave driving (Yulaeva et al. 1994) Link between planetary wave driving and Arctic T variability (Newmann et al. 2001)

EP (Heat) Flux and Residual Circulation

ozone production cold/warm winters heterogenous/gasphase chemistry Meridional circulation ~2-4 y EP (heat) flux Planetary scale wave activity Extratropical Pump Brewer-Dobson circulation Residual circulation Ozone & T variability chemistry/transport EP (Heat) Flux and Residual Circulation

Annual cycle of GOME and E39/C TOZ NH SH

Tropospheric forcing and spring/fall ozone ratio  GOME ozone ratio  50°-90°  Sep over Mar (SH) Mar over Sep (NH)  Winter heat flux  43°-70°  100 mbar  Sep-Mar (Mar-Sep) integrated and averaged SH anomaly 2002 Cold Arctic winter/spring seasons Weber et al  See Poster (Wohltmann et al.) for other met analyses and TOMS data

+5 m+6 m +8 m +7 m

spring/fall ratio for different months +10 m +11 m +9 m + 1 y

Ozone winter gain and summer transition  ERA40 vs UKMO  Interannual variability of winter heat flux correlates well with winter ozone gain  Winter heat flux higher in ERA40 (too much transport)  E39/C vs GOME  lower interannual variability in winter (NH)  weaker wave driving in SH (cold bias?)  Photochemical decay about 3m (>50°N) and 2.5 m (>62°N)  Good agreement between GOME and E39/C

Early 80s vs. late nineties  Correlation with ERA40 in early 80s and SH very poor ERA40

EP-Flux and polar ozone  TOMS/SBUV O3:  March 65°-70°N  NCEP EP-Flux:  15 Nov -28 Mar  100hPa  45°-75°N r=0.74  Lower correlation (0.69) in 80s  less O3 change for a given EP flux anomaly  Higher correlation (0.84) in 90s  more ozone transport for a given EP flux anomaly

Tropospheric forcing and chlorine activation  OClO  BrO+ClO –> OClO + O  Measured in twilight inside the polar vortex  Maximum vertical column at 90° solar zenith angle integrated over the winter  Below 92°SZA OClO is a measure of chlorine activation UKMO Weber et al High chlorine activation persisted during SH anomaly 2002

Dynamical control of chemical ozone loss EP-Flux Anomaly [10 5 kg /s 2 ] Dec-Mar total ozone change [DU]  See Poster (Wohltmann et al.) for detrailed transport & chemistry diagnostics of E39/C and ERA40  Sonde total columns  NH pol. vortex average  Chemical depleted column  Dec-Mar difference  Corrected for diabatic descent  Dynamical supply  Observed minus chemical depeleted column

Summary & Conclusion  Compact relationship between winter ozone gain and seasonal heat flux for both hemispheres (late nineties/early 2000)  Connection between chlorine activation/chemical loss to planetary wave driving can be explored  Summer ozone levels are tied to wave activity of the previous winter (see also Fioletov et al. 2003)  Met. Analyses  good measure of interannual variability  differences in strength of high latitude ozone transport varies (ERA40 higher than NCEP/UKMO)  Correlations between wave driving & ozone particularly well in 90s  E39/C (and possibly other CCMs)  less interannual variability in winter  Summer bias of 20% to observations at mid- to high latitude  No summer minimum in SH  Data still to be explored: GOME NO 2 and ENVISAT

Record high absolute lower stratospheric heat flux on 20th/21st September (ERA ) Splitting of the polar vortex on 26th September 2002 First major stratospheric warming in SH

ERA15/ERA40