Review of ozone and temperature lidar validations performed within the framework of the Network for the Detection of Stratospheric Change

Keckhut, Philippe; McDermid, Stuart; Swart, D. P. J.; McGee, Thomas J.; Godin‐Beekmann, Sophie; Adriani, A.; Barnes, John; Baray, Jean-Luc; Benchérif, Hassan; Claude, H.; Sarra, Alcide di; Fiocco, G.; Hansen, Georg; Hauchecorne, Alain; Leblanc, Thierry; Lee, Choo Hie; Pal, S. R.; Mégie, G.; Nakane, Hideaki; Neuber, Roland; Steinbrecht, Wolfgang; Thayer, J. P.

doi:10.1039/b404256e

Cited by 86 publications

(76 citation statements)

References 57 publications

(81 reference statements)

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“…In general, there exist 8-15 measurements in each month regardless of the season during the above mentioned periods. Detailed description of this LIDAR system is given in Keckhut et al (2004). Another LI-DAR has been operated in Sao Jose dos Campos, Brazil since 1972 and is mainly dedicated to the study of mesospheric sodium at the 589 nm resonant line in the 80-105 km altitude range (Batista et al, 2008).…”

Section: Lidar Measurementsmentioning

confidence: 99%

Long-term trends observed in the middle atmosphere temperatures using ground based LIDARs and satellite borne measurements

et al. 2014

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Abstract. Long-term data available from Lidar systems located at three different locations namely São José dos Campos, Brazil (23.2 • S, 45.8 • W), Gadanki (13.5 • N, 79.2 • E) and Reunion (20.8 • S, 55.5 • E) have been used to investigate the long-term variations like Annual, Semi-annual, Quasi-biennial, El Nino Southern Oscillation and solar cycle. These oscillations are also extracted from simultaneous satellite borne measurements of HALogen Occultation Experiment (HALOE) instrument onboard UARS and SABER onboard TIMED over these stations making largest time series covering the entire middle atmosphere. A good agreement is found between the LIDAR and satellite-derived amplitudes and phases between 30 and 65 km altitude, which suggests that satellite measurements can be used to investigate the long-term trends globally. Latter measurements are extended to 80 km in order to further investigate these oscillations. Large difference in the amplitudes between the eastern pacific and western pacific is noticed in these oscillations. Changing from cooling trends in the stratosphere to warming trends in the mesosphere occurs more or less at altitude around 70 km altitude and this result agrees well with that observed by satellite measurements reported in the literature. The peak in the cooling trend does not occur at a fixed altitude in the stratosphere however maximum warming trend is observed around 75 km at all the stations. The observed long-term trends including various oscillations are compared with that reported with various techniques.

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Section: Lidar Measurementsmentioning

confidence: 99%

Long-term trends observed in the middle atmosphere temperatures using ground based LIDARs and satellite borne measurements

et al. 2014

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“…All lidar systems participating in the EQUAL project (except the one operating from Esrange) are part of the Network for the Detection of Atmospheric Composition Change (NDACC, www.ndacc.org). Their measurements are regularly monitored for their quality via measurement and algorithm intercomparison campaigns performed under the NDACC protocol (Keckhut et al, 2004). Lidar profiles are routinely archived in the ENVISAT validation database at NILU (www.nilu.no).…”

Section: Comparison With Lidar Measurements In the Equal Projectmentioning

confidence: 99%

“…The temperature profile can be determined from the measurements using a seed value at the top of the profile, which is taken from statistical atmospheric models such as the MSIS90E model (Hedin, 1991). In an aerosol free atmosphere, temperatures are typically measured from 30 to around 60 km with an accuracy close to 1 K (Keckhut et al, 2004). Above this altitude the accuracy deteriorates rapidly.…”

Section: Validation Using Lidar Measurementsmentioning

confidence: 99%

Geophysical validation of temperature retrieved by the ESA processor from MIPAS/ENVISAT atmospheric limb-emission measurements

et al. 2007

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Abstract. The Michelson Interferometer for Passive Atmospheric Sounding (MIPAS) has been operating since March 2002 onboard of the ENVIronmental SATellite of the European Space Agency (ESA). The high resolution (0.035 cm −1 full width half maximum, unapodized) limb-emission measurements acquired by MIPAS in the first two years of operation have very good geographical and temporal coverage and have been re-processed by ESA with the most recent versions (4.61 and 4.62) of the inversion algorithms. The products of this processing chain are pressures at the tangent points and geolocated profiles of temperature and of the volume mixing ratios of six key atmospheric constituents: H 2 O, O 3 , HNO 3 , CH 4 , N 2 O and NO 2 . As for all the measurements made with innovative instruments and techniques, this data set requires a thorough validation. In this paper we present a geophysical validation of the temperature profiles derived from MIPAS measurements by the ESA retrieval algorithm. The validation is carried-out by comparing MIPAS temperature with Correspondence to: M.Ridolfi (Marco.Ridolfi@unibo.it) correlative measurements made by radiosondes, lidars, insitu and remote sensors operated either from the ground or stratospheric balloons.The results of the intercomparison indicate that the bias of the MIPAS profiles is generally smaller than 1 or 2 K depending on altitude. Furthermore we find that, especially at the edges of the altitude range covered by the MIPAS scan, the random error estimated from the intercomparison is larger (typically by a factor of two to three) than the corresponding estimate derived on the basis of error propagation.In this work we also characterize the discrepancies between MIPAS temperature and the temperature fields resulting from the analyses of the European Centre for Mediumrange Weather Forecasts (ECMWF). The bias and the standard deviation of these discrepancies are consistent with those obtained when comparing MIPAS to correlative measurements; however, in this case the detected bias has a peculiar behavior as a function of altitude. This behavior is very similar to that observed in previous studies and is suspected to be due to vertical oscillations in the ECMWF temperature.Published by Copernicus Publications on behalf of the European Geosciences Union. M.Ridolfi et al.: MIPAS temperature validationThe current understanding is that, at least in the upper stratosphere (above ≈10 hPa), these oscillations are caused by a discrepancy between model biases and biases of assimilated radiances from primarily nadir sounders.

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“…-the LI1200, a lidar dedicated to tropospheric water vapour (Hoareau et al, 2012;Dionisi et al, 2015;Vérèmes et al, 2017) and stratospheric-mesospheric temperature measurements (Morel et al, 2002;Keckhut et al, 2004Keckhut et al, , 2015Sivakumar et al, 2011a);…”

Section: Introductionmentioning

confidence: 99%

Tropospheric ozone profiles by DIAL at Maïdo Observatory (Reunion Island): system description, instrumental performance and result comparison with ozone external data set

et al. 2017

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Abstract. In order to recognize the importance of ozone (O 3 ) in the troposphere and lower stratosphere in the tropics, a DIAL (differential absorption lidar) tropospheric O 3 lidar system (LIO3T UR ) 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 O 3 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 m a.m.s.l. -metres above mean sea level) where it started operation in February 2013. The current system (LIO3T) configuration generates a 266 nm 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 nm beams to enable the use of the DIAL method for O 3 profile measurements. The optimal range for the actual system is 6-19 km a.m.s.l., depending on the instrumental and atmospheric conditions. For a 1 h integration time, vertical resolution varies from 0.7 km at 6 km a.m.s.l. to 1.3 km at 19 km a.m.s.l., and mean uncertainty within the 6-19 km range is between 6 and 13 %.

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Review of ozone and temperature lidar validations performed within the framework of the Network for the Detection of Stratospheric Change

Cited by 86 publications

References 57 publications

Long-term trends observed in the middle atmosphere temperatures using ground based LIDARs and satellite borne measurements

Long-term trends observed in the middle atmosphere temperatures using ground based LIDARs and satellite borne measurements

Geophysical validation of temperature retrieved by the ESA processor from MIPAS/ENVISAT atmospheric limb-emission measurements

Tropospheric ozone profiles by DIAL at Maïdo Observatory (Reunion Island): system description, instrumental performance and result comparison with ozone external data set

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