Abstract
Abstract. The remote sensing of total column water vapour (TCWV) from polar orbiting, sun-synchronous satellite spectrometers such as the Medium Resolution Imaging Spectrometer (MERIS) on board of ENVISAT and the Moderate Imaging Spectroradiometer (MODIS) on board of Aqua and Terra enables observations on a high spatial resolution and a high accuracy over land surfaces. The observations serve studies about small-scale variations of water vapour as well as the detection of local and global trends. However, depending on the swath width of the sensor, the temporal sampling is low and the observations of TCWV are limited to cloud-free land scenes. This study quantifies the representativeness of a single TCWV observation at the time of the satellite overpass under cloud-free conditions by investigating the diurnal cycle of TCWV using 9 years of a 2-hourly TCWV data set from global GNSS (Global Navigation Satellite Systems) stations. It turns out that the TCWV observed at 10:30 local time (LT) is generally lower than the daily mean TCWV by 0.65 mm (4 %) on average for cloud-free cases. Averaging over all GNSS stations, the monthly mean TCWV at 10:30 LT, constrained to cases that are cloud-free, is 5 mm (25 %) lower than the monthly mean TCWV at 10:30 LT of all cases. Additionally, the diurnal variability of TCWV is assessed. For the majority of GNSS stations, the amplitude of the averaged diurnal cycle ranges between 1 and 5 % of the daily mean with a minimum between 06:00 and 10:00 LT and maximum between 16:00 and 20:00 LT. However, a high variability of TCWV on an individual day is detected. On average, the TCWV standard deviation is about 15 % regarding the daily mean.
Highlights
Water vapour plays a key role in the hydrological cycle of the earth’s atmosphere
It turns out that the total column water vapour (TCWV) observed at 10:30 local time (LT) is generally lower than the daily mean TCWV by 0.65 mm (4 %) on average for cloud-free cases
TCWV derived from radiance measurements in the near-infrared (NIR) from space-borne spectrometers meets the requirement needed for weather forecasts and climate studies, due to high accuracy and high spatial resolution of the TCWV products
Summary
Water vapour plays a key role in the hydrological cycle of the earth’s atmosphere. The total column water vapour (TCWV) is a good indicator and/or tracer of atmospheric transport of water vapour. The ground-based measurements do not resolve the spatial structures of water vapour fields. They are usually limited to land areas. Observations from the MEdium Resolution Imaging Spectrometer (MERIS) (Bennartz and Fischer, 2001; Lindstrot et al, 2012) on ENVISAT and the Moderate Resolution Imaging Spectroradiometer (MODIS) on Aqua and Terra (Gao and Kaufman, 2003; Diedrich et al, 2015) can provide long time series of TCWV These data sets, such as those described by Lindstrot et al (2014), benefit global trend analysis or investigations of small-scale phenomena as described by Carbajal Henken et al (2015). We want to give an overview of the variability of TCWV that is needed for the interpretation of water vapour fields derived from remote sensing
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