UTLS water vapour from SCIAMACHY limb measurementsV3.01 (2002–2012)

Weigel, Katja; Rozanov, A.; Azam, Faiza; Bramstedt, K.; Damadeo, Robert; Eichmann, Kai‐Uwe; Gebhardt, Claus; Hurst, D. F.; Kraemer, M.; Lossow, Stefan; Read, W. G.; Spelten, N.; Stiller, G. P.; Walker, Kaley A.; Weber, Mark; Bovensmann, H.; Burrows, J. P.

doi:10.5194/amt-9-133-2016

Cited by 17 publications

(17 citation statements)

References 82 publications

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“…The 2σ error or uncertainty ranges also plotted indicate that the water vapour linear changes are not statistically significant at altitudes above 37 km and between 20 and 30 km where the change switches sign. A positive linear change in lower stratospheric water vapour during the time interval considered in this study has been observed by and Weigel et al (2016) mainly in the tropics. As already discussed in Noël et al (2016) methane linear changes are also not significant except for the lowest altitudes, where they are in general agreement with tropospheric trends.…”

Section: Linear Changessupporting

confidence: 62%

Water vapour and methane coupling in the stratosphere observed using SCIAMACHY solar occultation measurements

et al. 2018

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Abstract. An improved stratospheric water vapour data set has been retrieved from SCIAMACHY/ENVISAT solar occultation measurements. It is similar to that successfully applied to methane and carbon dioxide. There is now a consistent set of data products for the three constituents covering the altitudes 17-45 km, the latitude range between about 50 and 70 The combined analysis of the SCIAMACHY methane and water vapour time series shows the expected anti-correlation between stratospheric methane and water vapour and a clear temporal variation related to the Quasi-Biennial Oscillation (QBO). Above about 20 km most of the additional water vapour is attributed to the oxidation of methane. In addition short-term fluctuations and longer-term variations on a timescale of 5-6 years are observed. The SCIAMACHY data confirm that at lower altitudes the amount of water vapour and methane are transported from the tropics to higher latitudes via the shallow branch of the Brewer-Dobson circulation.

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Section: Linear Changessupporting

confidence: 62%

Water vapour and methane coupling in the stratosphere observed using SCIAMACHY solar occultation measurements

et al. 2018

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“…A comprehensive overview of commonly applied airborne instrumentation is given by Wendisch and Brenguier (2013). During the ML-CIRRUS and ACRIDICON-CHUVA campaigns, a set of remote sensing and in situ instruments was operated aboard HALO Voigt et al, 2017).…”

Section: Airborne Instrumentationmentioning

confidence: 99%

“…Molleker et al (2014) showed that the CCP exhibits a nominal limit for cloud particle diameters from 3 up to 50 µm. The CIPgs records twodimensional shadow images of cloud particles in a size range from 15 up to 960 µm with an optical resolution of 15 µm (Klingebiel et al, 2015;Weigel et al, 2016). Special algorithms are used to process and analyze the captured images in order to estimate particle number concentrations and particle size distributions, and to differentiate particle shapes (Korolev, 2007).…”

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confidence: 99%

Comparing airborne and satellite retrievals of cloud optical thickness and particle effective radius using a spectral radiance ratio technique: two case studies for cirrus and deep convective clouds

et al. 2018

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Abstract. Solar radiation reflected by cirrus and deep convective clouds (DCCs) was measured by the Spectral Modular Airborne Radiation Measurement System (SMART) installed on the German High Altitude and Long Range Research Aircraft (HALO) during the Mid-Latitude Cirrus (ML-CIRRUS) and the Aerosol, Cloud, Precipitation, and Radiation Interaction and Dynamic of Convective Clouds System -Cloud Processes of the Main Precipitation Systems in Brazil: A Contribution to Cloud Resolving Modelling and to the Global Precipitation Measurement (ACRIDICON-CHUVA) campaigns. On particular flights, HALO performed measurements closely collocated with overpasses of the Moderate Resolution Imaging Spectroradiometer (MODIS) aboard the Aqua satellite. A cirrus cloud located above liquid water clouds and a DCC topped by an anvil cirrus are analyzed in this paper. Based on the nadir spectral upward radiance measured above the two clouds, the optical thickness τ and particle effective radius r eff of the cirrus and DCC are retrieved using a radiance ratio technique, which considers the cloud thermodynamic phase, the vertical profile of cloud microphysical properties, the presence of multilayer clouds, and the heterogeneity of the surface albedo. For the cirrus case, the comparison of τ and r eff retrieved on the basis of SMART and MODIS measurements yields a normalized mean absolute deviation of up to 1.2 % for τ and 2.1 % for r eff . For the DCC case, deviations of up to 3.6 % for τ and 6.2 % for r eff are obtained. The larger deviations in the DCC case are mainly attributed to the fast cloud evolution and three-dimensional (3-D) radiative effects. Measurements of spectral upward radiance at near-infrared wavelengths are employed to investigate the vertical profile of r eff in the cirrus. The retrieved values of r eff are compared with corresponding in situ measurements using a vertical weighting method. Compared to the MODIS observations, measurements of SMART provide more information on the vertical distribution of particle sizes, which allow reconstructing the profile of r eff close to the cloud top. The comparison between retrieved and in situ r eff yields a normalized mean absolute deviation, which ranges between 1.5 and 10.3 %, and a robust correlation coefficient of 0.82.

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“…The 2σ uncertainty ranges also plotted indicate that the water vapour trends are not significant in a statistical sense at altitudes above 37 km and between 20 and 30 km where the trend switches sign. A positive trend in lower stratospheric water vapour during the time interval considered in this study has been observed by Urban et al (2014) and Weigel et al (2016) mainly in the tropics. As already discussed in Noël et al (2016) methane trends are also not significant except for the lowest altitudes, where they are in general agreement with tropospheric trends.…”

Section: Potential Watermentioning

confidence: 83%

Water Vapour and Methane Coupling in the Stratosphere observed with SCIAMACHY Solar Occultation Measurements

Noël¹,

Weigel²,

Bramstedt³

et al. 2017

Preprint

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Abstract.An improved stratospheric water vapour data set has been derived from SCIAMACHY/ENVISAT solar occultation measurements. It is based on the same algorithm which has already been successfully applied to methane and carbon dioxide retrievals, thus resulting in a consistent data set for theses three constituents covering the altitudes 17-45 km, the latitude range between about 50 and 70 ).The combined analysis of the SCIAMACHY methane and water vapour time series reveals that stratospheric methane and water vapour are strongly correlated and show a clear temporal variation related to the Quasi-Biannual-Oscillation (QBO). 10Above about 20 km most of the water vapour seems to be produced by methane, but short-term fluctuations and a temporal variation on a scale of 5-6 years are observed.At lower altitudes the balance between water vapour and methane is affected by stratospheric transport of water vapour and methane from the tropics to higher latitudes via the shallow branch of the Brewer-Dobson circulation and by the increasing methane input into the stratosphere due to the rise of tropospheric methane after 2007.

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UTLS water vapour from SCIAMACHY limb measurementsV3.01 (2002–2012)

Cited by 17 publications

References 82 publications

Water vapour and methane coupling in the stratosphere observed using SCIAMACHY solar occultation measurements

Water vapour and methane coupling in the stratosphere observed using SCIAMACHY solar occultation measurements

Comparing airborne and satellite retrievals of cloud optical thickness and particle effective radius using a spectral radiance ratio technique: two case studies for cirrus and deep convective clouds

Water Vapour and Methane Coupling in the Stratosphere observed with SCIAMACHY Solar Occultation Measurements

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