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Tropospheric ozone climatology at extratropical latitudes O.A. Tarasova (1), A.M. Zvyagintsev (2), G. Kakajanova (2), I.N. Kuznetsova (3) (1) (1) Faculty of Physics, Lomonosov Moscow State University, Moscow, Russia OTarasova@yandex.ru OTarasova@yandex.ru (2) (2) Central Aerological Observatory of Russian Hydrometeorological Center, Dolgoprudny, Moscow region, Russia, (3) (3) Hydrometeorological State Research Center of Russia, Moscow, Russia The work is carried out in the frames of ACCENT project EGU General Assembly 2006, Vienna
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“What do we know about tropospheric ozone?” or Objectives Its nature is still unclear The spring maximum is a Northern Hemispheric phenomenon. It occurs widely across mid-latitudes in the Northern Hemisphere. Its nature is still unclear Is it trueout of the mid-latitudes of the Northern Hemisphere The phenomenon occurs with different timing and magnitude in the boundary layer and lower free troposphere as compared to the upper troposphere. Is it true out of the mid-latitudes of the Northern Hemisphere? Can we say anything about global gradients? There are apparent latitude/longitude gradients in the shape of the seasonal cycle over Europe. On the western edge of Europe there are sites with a spring maximum/summer minimum. This is followed by a band of sites with a spring time maximum followed by a broad decrease in ozone towards autumn. Finally, in the interior of Europe measurement sites display a broad summer maximum. Can we say anything about global gradients? Can it help us to interpret observed seasonality? Diurnal cycle is characterized by afternoon maximum at non-elevated sites and at night concentration maximum at the elevated ones. Can it help us to interpret observed seasonality? Is it “local” phenomenon? By the ozone sondes measurements in the north Pacific it was shown that in general the prominent spring maximum is observed throughout the troposphere being tied to the jet stream. Is it “local” phenomenon? Oltmans, S. J., et al. (2004), Tropospheric ozone over the North Pacific from ozonesonde observations, J. Geophys. Res.,109, D15S01, doi:10.1029/2003JD003466. Monks, P.S, A review of the observations and origins of the spring ozone maximum, Atmospheric Environment 34 (2000) 3545-3561
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Ozone measurements networks (long time series)
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Approach used Long-term measurements are selected Long-term measurements are selected Mean seasonal cycle with 1 hour resolution is calculated Mean seasonal cycle with 1 hour resolution is calculated Obtained seasonal cycles are classified by K-means clusters Obtained seasonal cycles are classified by K-means clusters Center of clusters are analyzed Center of clusters are analyzed Amplitude of seasonal/diurnal variations is estimated for each cluster for each hour/month. Amplitude of seasonal/diurnal variations is estimated for each cluster for each hour/month.
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EMEP network: 5 clusters results
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Rural and semi-pollutedSemi-elevated Clean (remote)High-mountainIspra
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Clusters of sites according to seasonal- diurnal variability shape (EMEP+WDCGG)
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EMEP+WDCGG network: Seasonal – diurnal cycles clustering Clean sites – spring maximum
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EMEP+WDCGG network: Seasonal – diurnal cycles clustering Semi-polluted and semi-elevated – double maximum with spring dominating
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EMEP+WDCGG network: Seasonal – diurnal cycles clustering Rural – spring maximum and autumn minimum with bigger amplitude than for clean group
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EMEP+WDCGG network: Seasonal – diurnal cycles clustering Elevated – double maximum with spring dominating and nigh diurnal maximum
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EMEP+WDCGG network: Seasonal – diurnal cycles clustering Polluted – double maximum with summer dominating
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Shift of seasonality for the sites with double maximum
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Surface ozone seasonal series in the Southern hemisphere
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Ozone sondes launch-sites LatitudeLongitudeHeightPeriod Number of profiles KAGOSHIMA31,55130,550,0311969-2003665 SAPPORO43,05141,3330,0191968-2003703 TATENO36,05140,10,0311968-2003903 ALERT82,5-62,30,0621987-2002619 EDMONTON53,55-114,10,7661970-2002980 RESOLUTE74,72-94,980,0641966-2001869 BOULDER40,03-105,251,6891963-20031198 GOOSE BAY53,32-60,30,0441963-20021100 CHURCHILL58,75-94,070,0351973-2002863 HOHENPEISSENBERG47,811,020,9751966-20033591 SYOWA-6939,580,0211966-2003640 WALLOPS ISLAND37,933-75,4830,0131970-1992452 HILO19,717-155,0670,0111982-2003760 PAYERNE46,496,570,4911968-20023682 LINDENBERG52,2514,120,1121975-20031246 NAHA26,2127,6830,0271989-2003434 MARAMBIO-64,233-56,7170,1961988-1998246 LAVERTON-37,867144,750,0211982-1999360 LEGIONOWO52,420,9670,0961979-2003633 SODANKYLA67,3926,650,1791988-1998628 SOUTH POLE-9002,8351986-2003538
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Seasonal – altitudinal distribution of ozone concentration (ozonesondes – WOUDC) 67N-83N 53N-59N
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Seasonal – altitudinal distribution of ozone concentration (ozonesondes – WOUDC) 48N-53N 40N-47N
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Seasonal – altitudinal distribution of ozone concentration (ozonesondes – WOUDC) 36N-38N 19N-32N
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Seasonal – altitudinal distribution of ozone concentration (ozonesondes – WOUDC) Southern Hemisphere Impact of the spring Antarctic ozone anomaly is observed at all Antarctica station to a greater or lesser extent
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Conclusions In general ozone concentration in the troposphere is lower in the Southern hemisphere BUT it has similar features as in the Northern hemisphere. In general ozone concentration in the troposphere is lower in the Southern hemisphere BUT it has similar features as in the Northern hemisphere. Ozone seasonal cycle is observed between winter and summer in both hemispheres. Ozone seasonal cycle is observed between winter and summer in both hemispheres. At the high and mid latitudes of the both hemispheres seasonal maximum of the surface ozone is observed in winter – beginning of spring and its position in time does not depend on the local time. It is observed thought whole troposphere. Spring maximum is likely to have dynamical nature At the high and mid latitudes of the both hemispheres seasonal maximum of the surface ozone is observed in winter – beginning of spring and its position in time does not depend on the local time. It is observed thought whole troposphere. Spring maximum is likely to have dynamical nature Moving to the South, time of the maximum shifts to summer months and the structure of the seasonal variability gets more complicated. As summer maximum is observed only for daily ozone (2 months earlier than for night seasonal maximum) and only in the low troposphere it is likely to have a photochemical nature. Moving to the South, time of the maximum shifts to summer months and the structure of the seasonal variability gets more complicated. As summer maximum is observed only for daily ozone (2 months earlier than for night seasonal maximum) and only in the low troposphere it is likely to have a photochemical nature. There are several distinct seasonal-diurnal structures of the surface ozone variability with spring, spring-summer and summer seasonal maximum. It is difficult to make any conclusion about global spatial gradients of the seasonal-diurnal variability shape. Only slight latitudinal shift of variability amplitudes is observed. There are several distinct seasonal-diurnal structures of the surface ozone variability with spring, spring-summer and summer seasonal maximum. It is difficult to make any conclusion about global spatial gradients of the seasonal-diurnal variability shape. Only slight latitudinal shift of variability amplitudes is observed. Spring ozone anomaly impacts the seasonality observed at the sonding sites in Antarctica. Spring ozone anomaly impacts the seasonality observed at the sonding sites in Antarctica.
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