Refine
Year of publication
- 2010 (1) (remove)
Document Type
- Doctoral Thesis (1)
Language
- English (1)
Has Fulltext
- yes (1)
Is part of the Bibliography
- no (1)
Keywords
- Troposphäre (1) (remove)
Institute
The TTL is the transition layer between the tropical troposphere and stratosphere, and is the main region where tropospheric air enters the stratosphere. In this thesis different transport processes are studied by using in situ measurements of tracers. Long-lived tracers were measured with the High Altitude Gas Analyzer (HAGAR) on board the M55 Geophysica aircraft. The instrument was developed by the University of Frankfurt and measures the long-lived tracers CO2, N2O, CFC-12, CFC-11, H-1211, SF6, CH4 and H2 with two gas chromatographic channels and a CO2 sensor (LICOR). The measurements are supported by CO and O3 measurements of other instruments. Two campaigns were conducted to obtain measurements in the TTL: SCOUT-O3 (November/December 2005 in Darwin, Australia) and AMMA-SCOUT-O3 (August 2006 in Ouagadougou, Burkina Faso). After a general introduction of the thesis in chapters one and two, the third chapter describes the findings during this last campaign. Five local flights are analyzed to study the different transport processes that occur in the tropical tropopause layer above West-Africa: deep convection up to the level of main convective outflow, vertical mixing after overshooting of air in deep convection, horizontal inmixing from the extratropical lower stratosphere, and horizontal transport across the subtropical barrier. Main findings are that the TTL over West-Africa is mostly influenced by remote convection. The subtropical barrier is not a strong barrier but more a region of transition between the extratropical and the tropical stratosphere. Chapter 4 presents the results obtained during the SCOUT-O3 campaign. From the eight local flights the last four flights (051129, 051130a, 051130b, 051205) show enhanced values of ozone, CO and CO2 between 355 and 380 K potential temperature in comparison with the first four flights (051116, 051119, 051123, 051125). Horizontal inmixing from the extra-tropical stratosphere and influence of the local convective system Hector cannot explain the enhanced values of the two flights on 30 November Therefore, other possible explanations for these enhanced CO, CO2 and ozone levels are proposed. The first explanation is vertical mixing in the vicinity of the jet stream. However, the jet cannot explain the differences between the flights on 30 November and the flights on 29 November and 5 December. Another possible explanation is influence of polluted boundary layer air masses from the Indonesian region. Especially air sampled during the flights on November 30 crossed large parts of northern Indonesia between 8 and 10 days before the measurements. Convective uplift of biomass burning and other pollution plumes can transport CO and ozone precursors into the upper troposphere, where they can significantly enhance the ozone production. The last chapter deals with the vertical ascent rate in the TTL and uses measurements of both the SCOUT-O3 and AMMA-SCOUT-O3 campaign as well as data from previous aircraft campaigns (TROCCINOX and APE-THESEO). Time scales and residence times for mean vertical transport in the background TTL are estimated for different seasons and over different geographic regions using in situ observations of CO2 and long-lived tracers. The vertical transport time scales are constrained using the seasonal variation of CO2 in the tropical troposphere as a “tracer clock” for vertical ascent. Two methods are applied to calculate the residence time in the layer between 360 and 390 K potential temperature. The first method uses the slope of the CO2 index, the second method fits the CO2 index directly to the measurements assuming a constant ascent rate. The first method yields residence times for Australia,West Africa, and Brazil of the same order, 35-45 days to 380 K and 50 days to 390 K (where no value can be derived for Australia as the slope is changing approximately one month before the campaign). For APE-THESEO, the method does not yield reasonable results. The best estimates using the second method show moderate residence times between 360 and 390 K of 60±25 days SCOUT-O3 (NH autumn) and 43±8 days for AMMA/SCOUT-O3 (NH summer). These results agree well with the results calculated using the first method. For APE-THESEO and TROCCINOX the best fits yield shorter residence times of 23±7 and 40±10 days, respectively, both during winter. These results correspond well to the expectations based on the seasonal variation of the Brewer-Dobson circulation.