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Stephan Borrmann Kathy Law (Univ. Paris-Jussieu) Daniel Kunkel, Joachim Curtius (Univ. of Mainz and MPIC) Ralf Weigel (Univ. Clermont-Ferrand) Silvia Viciani.

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Presentation on theme: "Stephan Borrmann Kathy Law (Univ. Paris-Jussieu) Daniel Kunkel, Joachim Curtius (Univ. of Mainz and MPIC) Ralf Weigel (Univ. Clermont-Ferrand) Silvia Viciani."— Presentation transcript:

1 Stephan Borrmann Kathy Law (Univ. Paris-Jussieu) Daniel Kunkel, Joachim Curtius (Univ. of Mainz and MPIC) Ralf Weigel (Univ. Clermont-Ferrand) Silvia Viciani (INOA, Florence) G. Shur, A. Ulanovsky (CAO, Moscow, Russia) Ultrafine particles in the West African UT/LS: In-situ measurements in August 2006 during the AMMA monsoon period 2007 EGU General Assembly, AS 1.14 – 1 FR4O-001

2 (1) Instrument: COPAS on Russian high altitude research aircracft M-55 „Geophysica“

3 heated channel (250°C) -Condensable liquid: Fluorinert - 1 Hz data -  10% - isokinetic inlet < 1µm Specialized CPC type COndensation PArticle counting System unheated channel

4 1 Hz time series/vertical profiles up to 20 km of particle # / cm³ * for sizes > 6 nm * for size diam. > 10 nm * for size diam. > 14 nm * above 10 nm after heating to 250 °C => non volatile residue * derived: Fraction f of non volatile to total # for > 10 nm COPAS Deliverables

5 2 Modified FSSP-SPP100 1 Cloud Imaging Probe CIP 2 COPAS units UMAINZ/MPIC instrumentation on „Geophysica“ COPAS I COPAS II

6 Russian M-55 „Geophysica“ (20 km ceiling)

7 (2) Results: „Global“ background aerosol between potential temperatures Θ of 367 K and 460 K

8 TROCCINOX, SCOUT-O3, AMMA transfer flights Latitude range: 55 °N to 20 °S, Jan 2005 until Aug 2006, no major volcano eruption Marrakesh Marocco Ouagadougou Burina Faso Accra Ghana Verona Italy

9 Marrakech-Ouagadougou Heated 10 nm channel „Cold“ 10 nm channel Pressure hPa]

10 -●- n 6 TROCCINOX–Transfer Germany - Brazil -●- n 6 SCOUT – Transfer Germany - Australia Θ, altitude range ≈ 367 K to 460 K ≈ 12 km to 17 km AMMA transfer

11 (3) Results: Vertical profiles Mid-latitudes, Brazil, Australia, West-Africa

12 -●- EUPLEX- Test, Forli, 2002 ― CN, Laramie, USA, Deshler et al. 2003 ● Marshal Test flight, OPH 2005 ● SCOUT-Transfer, OPH - Larnaca, 2005 ● SCOUT-Transfer, Larnaca - OPH, 2005 -●- AMMA 2006, mid-latitude flights Mid latitude vertical profiles 2002 to 2006 1999, 41°N 2005 2005 35°N 2002, 44°N 2005, 48°N July 2006 Remar- kably konstant from 1999 until 2006

13 ● 04.11.2005 OPH - Larnaca ● 04.11.2005 Larnaca - Dubai ● 07.11.2005 Dubai – Hyderabad ● 09.11.2005 Hyderabad – U-Tapao ● 11.11.2005 U-Tapao - Brunei ● 12.11.2005 Brunei – Darwin ● 09.12.2005 Darwin - Brunei ● 10.12.2005 Brunei – U-Tapao ● 13.12.2005 U-Tapao – Hyderabad ● 14.12.2005 Hyderabad - Dubai ● 16.12.2005 Dubai - Larnaca ● 17.12.2005 Larnaca - OPH COPAS-data vs altitude particle sizes > 6 nm  1 µm SCOUT-O3 transfer flights Germany – Australia Nov. and Dec. 2005 Tropospheric variability Stratospheric compactness

14 SCOUT-O3 local flights Darwin, Australia ● 16.11.2005 ● 19.11.2005 ● 23.11.2005 ● 25.11.2005 ● 29.11.2005 ● 30.11.2005 A ● 30.11.2005 B ● 05.12.2005 Contrail crossing ? COPAS-data vs altitude particle sizes > 6 nm  1 µm

15 ● n 10 non-volatile ● n 10 total ● n 14 ● n 6 -●- median n 10 COPAS-data vs altitude particle sizes > 6 nm  1 µm AMMA local flights Ouagadougou: * Unusual increase above 450 K * Compact data with very little scatter * No nucleation particles Particle number concentration [cm³] Potential Temperature [K]

16 Amma Darwin Brazil Brock, 1995 Potential temperature [K] Particle mixing ratio [#/mg] Context of other tropical data from „Geophysica“: Vertical profiles Tropical Brazil, Australia, West-Africa => W. African profile IS unusual.

17 All AMMA flights: Red: θ = 500 K Blue: θ = 350 K „Anomaly“ also in „N 2 O space“

18 Except AMMA all data from Chuck Wilson, Denver University, ER-2 and WB-57 tropical measurements from 1996 onward Ultrafine particle mixing ratio [#/mg of air] Potential temperature [K] Context with other tropical data

19 (4) Results: nonvolatile ultrafine particles ( > 10 nm and  1 µm ) (nonvolatile) particle number above 10 nm per cm³ of air (250 °C) total particle number density > 10 nm (ambient temperature) f = nonvolatile residues ambient particles = « »

20 Mid latitudes ― Brock et al. (1995) outside tropics -●- COPAS n 10 – median (2002) Arctic Latitudes -●- COPAS n 10 inside polar vortex (2003) -○- COPAS n 10 outside polar vortex (2003) Tropics ― Brock et al. (1995) inside tropics -●- COPAS n 10 Brasil (2005) -●- COPAS n 10 Australia (2005) Striking increase inside 2003 arctic vortex above 400 K

21 EXAMPLE: Arctic data 2003 high fraction of non-volatile particles inside Arctic vortex (~70 %) Curtius et al., ACP, 2005 EUPLEX 2003 Ratio of non-volatile particle number to total particle number > 10nm, < 1 µm => subsidence of meteoritic material from mesosphere

22 Mid latitudes ― Brock et al. (1995) outside tropics -●- COPAS n 10 – median (2002) Arctic Latitudes -●- COPAS n 10 inside polar vortex (2003) -○- COPAS n 10 outside polar vortex (2003) Tropics ― Brock et al. (1995) inside tropics -●- COPAS n 10 Brasil (2005) -●- COPAS n 10 Australia (2005) Striking increase inside 2003 arctic vortex above 400 K Explained by IMPORT of meteoric dust from the mesosphere through analysis of non-volatility

23 TROPICAL BRASIL Non-volatile particles constant at 20-30% in LS More variable, but typically ~10% in TTL and below. Ratio of non-volatile particle number to total particle number > 10nm, < 1 µm 2005 0123 - 0227

24 AUSTRALIA 2005 Slightly higher level (10%) of non-volatile particles over the continent than above the sea Ratio of non-volatile particle number to total particle number > 10nm, <1 µm continental Australia tropical „oceanic“ Australia

25 AMMA: Ouaga ratio of non volatile particles to total number * Values above 360K are at 50%. * Tropical Brazil was 20%. * Tropical Australia 60% but higher up. 4.8.2006 8.8.2006 11.8.2006

26 ● n 10 non-volatile ● n 10 total ● n 14 ● n 6 -●- median n 10 AMMA summary: COPAS-data vs altitude particle sizes > 6 nm  1 µm Ouagadougou local flights „Tropospheric variability region“ „Sulfuric acid region“ „Region of high non volatility“ Particle number concentration [cm³] Potential Temperature [K]

27 (5) Results from specific cases: Biomass burning particles

28

29

30 High CO for biomass burning is correlated with high ultrafine particle Number densities

31 AMMA flight August 8, 2006 High CO for biomass burning is correlated with high non-volatile ultrafine particle component Theta: Blue 370 K Grey 385 K Yellow 400 K Red 430 K

32 Biomass burning: Vertical profiles over Accra, August 13, 2006 Difference between n6 and n14 is zero. Thus: no new particle formation in bmb plume above Accra

33 Direct evidence for homogeneous nucleation in the tropics ● n 6 ● n 15 – altitude Flight altitude in km Non volatile component f ≈ 30% at 13 km altitude Homogeneous Nucleation Particle number density in cm -3 Only ultrafine particles 6 nm  size  14 nm UTC flight time [hours] TROCCINOX, BRAZIL, 24.2.2005

34 Biomass burning: Vertical profiles over Accra, August 4, 2006

35 Large latitudinal data sets on non-volcanic background ultrafine particles within 2005 through TROCCINOX, SCOUT-O3, AMMA mid-lat. transfer, survey, test flights. For AMMA unexpected increase above 420 K => No explanation sofar. Non-volatility vs. total aerosol number ratios between 20% and 80%, maximum near 400 K => No explanation for this profile sofar. Above ≈ 400 K ultrafine particle numbers constant since 1999 at mid-latitudes Summary

36

37 Thanks for your interest.

38 Heater efficiency of COPAS I at 250°C with pure H 2 O- H 2 SO 4 - particles Boiling point of H 2 O- H 2 SO 4 particles under pressure conditions at 10 – 20 km: ~ 150°C (Rosen, 1971) ● not heated channel ● heated channel at 250°C ○ 300 hPa ∆ 150 hPa ◊ 70 hPa particle diameter in nm particle number concentration in cm -3 (log) particle number density in cm -3 (linear) H 2 SO 4 /H 2 O 150nm particles with 0.5% by volume nonvolatile component will be detected as „non-volatile“.

39 Hector Cb-cloud flights vs. continental Australia flight ● Hector flight, 25.11.2005 ● Hector flight, 30.11.2005 A ● Hector flight, 30.11.2005 B ● ENVISAT flight, 05.12.2005 SCOUT-O3 Australia 2005

40 Red : Darwin Dec. 2005 Green: Aracatuba, Brazil Feb 2005 Black: mid-lat blue: arctic COPAS n > 10 nm

41 Import of ultrafine nuclei from high altitudes inside polar vortex Particle number mixing ratio in [ # / mg ] N 2 O mixing ratio in [ ppbv ] EXAMPLE: Arctic data 2003 Correlation of ultrafine particles with long lived tracer N 2 O Curtius et al., ACP, 2005

42 ● n 10 non-volatile ● n 10 total -○- median n 10 Verona Marrakech Are data ok ? Mid-latitude parts of AMMA transfer consistent with other profiles.

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