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dc.contributor.authorDuflot, V.
dc.contributor.authorBaray, J.-L.
dc.contributor.authorPayen, G.
dc.contributor.authorMarquestaut, N.
dc.contributor.authorPosny, F.
dc.contributor.authorMetzger, J.-M.
dc.contributor.authorLangerock, B.
dc.contributor.authorVigouroux, C.
dc.contributor.authorHadji-Lazaro, J.
dc.contributor.authorPortafaix, T.
dc.contributor.authorDe Mazière, M.
dc.contributor.authorCoheur, P.-F.
dc.contributor.authorClerbaux, C.
dc.contributor.authorCammas, J.-P.
dc.date2017
dc.date.accessioned2017-11-24T12:48:11Z
dc.date.available2017-11-24T12:48:11Z
dc.identifier.urihttps://orfeo.belnet.be/handle/internal/6300
dc.descriptionIn order to recognize the importance of ozone (O3) in the troposphere and lower stratosphere in the tropics, a DIAL (differential absorption lidar) tropospheric O3 lidar system (LIO3TUR) was developed and installed at the Université de la Réunion campus site (close to the sea) on Reunion Island (southern tropics) in 1998. From 1998 to 2010, it acquired 427 O3 profiles from the low to the upper troposphere and has been central to several studies. In 2012, the system was moved up to the new Maïdo Observatory facility (2160-l. - metres above mean sea level) where it started operation in February 2013. The current system (LIO3T) configuration generates a 266 beam obtained with the fourth harmonic of a Nd:YAG laser sent into a Raman cell filled up with deuterium (using helium as buffer gas), generating the 289 and 316 beams to enable the use of the DIAL method for O3 profile measurements. The optimal range for the actual system is 6-19ga.m.s.l., depending on the instrumental and atmospheric conditions. For a 1gh integration time, vertical resolution varies from 0.7gkm at 6ga.m.s.l. to 1.3gkm at 19ga.m.s.l., and mean uncertainty within the 6-19gkm range is between 6 and 13g%. Comparisons with eight electrochemical concentration cell (ECC) sondes simultaneously launched from the Maïdo Observatory show good agreement between data sets with a 6.8g% mean absolute relative difference (<i>D</i>) between 6 and 17ga.m.s.l. (LIO3T lower than ECC). Comparisons with 37 ECC sondes launched from the nearby Gillot site during the daytime in a ±24gh window around lidar shooting result in a 9.4g% <i>D</i> between 6 and 19ga.m.s.l. (LIO3T lower than ECC). Comparisons with 11 ground-based Network for Detection of Atmospheric Composition Change (NDACC) Fourier transform infrared (FTIR) spectrometer measurements acquired during the daytime in a ±24gh window around lidar shooting show good agreement between data sets with a <i>D</i> of 11.8g% for the 8.5-16gkm partial column (LIO3T higher than FTIR), and comparisons with 39 simultaneous Infrared Atmospheric Sounding Interferometer (IASI) observations over Reunion Island show good agreement between data sets with a <i>D</i> of 11.3g% for the 6-16gkm partial column (LIO3T higher than IASI). ECC, LIO3TUR and LIO3T O3 monthly climatologies all exhibit the same range of values and patterns. In particular, the Southern Hemisphere biomass burning seasonal enhancement and the ozonopause altitude decrease in late austral winter-spring, as well as the sign of deep convection bringing boundary layer O3-poor air masses up to the middle-upper troposphere in late austral summer, are clearly visible in all data sets.
dc.languageeng
dc.titleTropospheric ozone profiles by DIAL at Maïdo Observatory (Reunion Island): system description, instrumental performance and result comparison with ozone external data set
dc.typeArticle
dc.subject.frascatiEarth and related Environmental sciences
dc.audienceScientific
dc.source.titleAtmospheric Measurement Techniques
dc.source.volume10
dc.source.issue9
dc.source.page3359-3373
Orfeo.peerreviewedYes
dc.identifier.doi10.5194/amt-10-3359-2017
dc.identifier.scopus2-s2.0-85029471830


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