Abstract
To date, a large variety of water vapour data records from satellite and reanalysis are available. It is key to understand the quality and uncertainty of these data records in order to fully exploit these records and to avoid data being employed incorrectly or misinterpreted. Therefore, it is important to inform users on accuracy and limitations of these data records based on consistent inter-comparisons carried out in the framework of international assessments. Addressing this challenge is the major objective of the Global Water and Energy Exchanges (GEWEX) water vapor assessment (G-VAP) which was initiated by the GEWEX Data and Assessments Panel (GDAP). Here, an overview of G-VAP objectives and an introduction to the results from G-VAP’s first phase are given. After this overview, a summary of available data records on water vapour and closely related variables and a short introduction to the utilized methods are presented. The results from inter-comparisons, homogeneity testing and inter-comparison of trend estimates, achieved within G-VAP’s first phase are summarized. The conclusions on future research directions for the wider community and for G-VAP’s next phase are outlined and recommendations have been formulated. For instance, a key recommendation is the need for recalibration and improved inter-calibration of radiance data records and subsequent reprocessing in order to increase stability and to provide uncertainty estimates. This need became evident from a general disagreement in trend estimates (e.g., trends in TCWV ranging from −1.51 ± 0.17 kg/m2/decade to 1.22 ± 0.16 kg/m2/decade) and the presence of break points on global and regional scale. It will be a future activity of G-VAP to reassess the stability of updated or new data records and to assess consistency, i.e., the closeness of data records given their uncertainty estimates.
Highlights
Satellite observations allow global monitoring of various parameters of the global water and energy cycle, including water vapour
In the majority of cases (67%) the standard normal homogeneity (SNH) test confirms the presence of break points detected by the Penalised Maximal F (PMF) test over Sc Pacific while over western Africa only 29% of the break points from the PMF test are confirmed by results from the SNH test
In view of the results of recent efforts on assigning uncertainties to ground-based, in situ, satellite and reanalysis data, it is recommended by G-VAP that activities on the validation of data records and within assessments need to make use of available uncertainty estimates to assess the degree of consistency
Summary
Satellite observations allow global monitoring of various parameters of the global water and energy cycle, including water vapour. G-VAP organises annual workshops to provide opportunities for (i) presenting state-of-the-art of water vapour retrievals and products, (ii) discussion of results from inter-comparisons exercises and quantifying the sources of observed differences, and (iii) providing recommendations for future directions and roadmap It was consensus at the G-VAP workshops to continue G-VAP beyond the finalisation of the World Climate Research Programme (WCRP) report on G-VAP, with support from GDAP. The G-VAP analysis includes bias and standard deviation relative to the ensemble mean, break point analysis, trend estimation and inter-comparison of trends, and computing the regression between changes in water vapour and sea surface temperature (SST) These methodologies are consistently applied to the full suite of available long-term, gridded data records.
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