Home > Publications database > Lightning NOx influence on large-scale NOy and O3 plumes observed over the northern mid-latitudes > print

001     172736
005     20240712101007.0
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|a 10.3402/tellusb.v66.25544
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|a 0280-6509
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037 _ _ |a FZJ-2014-06180
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100 1 _ |0 P:(DE-HGF)0
|a Gressent, Alicia
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|e Corresponding Author
245 _ _ |a Lightning NOx influence on large-scale NOy and O3 plumes observed over the northern mid-latitudes
260 _ _ |a Stockholm
|b Inst.
|c 2014
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520 _ _ |a This paper describes the NOy plumes originating from lightning emissions based on 4 yr (2001–2005) of MOZAIC measurements in the upper troposphere of the northern mid-latitudes, together with ground- and space-based observations of lightning flashes and clouds. This analysis is primarily for the North Atlantic region where the MOZAIC flights are the most frequent and for which the measurements are well representative in space and time. The study investigates the influence of lightning NOx (LNOx) emissions on large-scale (300–2000 km) plumes (LSPs) of NOy. One hundred and twenty seven LSPs (6% of the total MOZAIC NOy dataset) have been attributed to LNOx emissions. Most of these LSPs were recorded over North America and the Atlantic mainly in spring and summer during the maximum lightning activity occurrence. The majority of the LSPs (74%) is related to warm conveyor belts and extra-tropical cyclones originating from North America and entering the intercontinental transport pathway between North America and Europe, leading to a negative (positive) west to east NOy (O3) zonal gradient with −0.4 (+18) ppbv difference during spring and −0.6 (+14) ppbv difference in summer. The NOy zonal gradient can correspond to the mixing of the plume with the background air. On the other hand, the O3 gradient is associated with both mixing of background air and with photochemical production during transport. Such transatlantic LSPs may have a potential impact on the European pollution. The remaining sampled LSPs are related to mesoscale convection over Western Europe and the Mediterranean Sea (18%) and to tropical convection (8%).
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|a Sauvage, Bastien
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|a Defer, Eric
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|a Pätz, Hans-Werner
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|a Thomas, Karin
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|a Holle, Ronald
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|a Cammas, Jean-Pierre
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|a Nédélec, Philippe
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|a Boulanger, Damien
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|a Thouret, Valérie
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|a Volz-Thomas, Andreas
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856 4 _ |u http://dx.doi.org/10.3402/tellusb.v66.25544
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