Global Soil Moisture Patterns Observed by Space Borne Microwave Radiometers and Scatterometers

Jeu, de R.A.M.; Wagner, Wolfgang; Holmes, Thomas; Dolman, A. J.; Giesen, van de N.C.; Friesen, Jan

doi:10.1007/s10712-008-9044-0

Cited by 330 publications

(179 citation statements)

References 66 publications

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“…However, numerous studies in the past have shown that satellite-derived surface soil moisture is strongly related to the 0-0.05 m soil layer (e.g. Wagner et al, 2007;De Jeu et al, 2008;Draper et al, 2009;Gruhier et al, 2010). Therefore in GLEAM, satellite observations of soil moisture (θ) are assimilated with the modelled water content of the first soil layer (w (1) ) that is predicted by Eq.…”

Section: Satellite Surface Soil Moisture Assimilationmentioning

confidence: 99%

“…This implies that the value of K will be fully determined by the estimation of the variance error in the microwave observations (V ). According to De Jeu et al (2008), the vegetation optical depth (τ ) can be used to approximate the polynomial relation existing between the uncertainty of the microwave soil moisture retrieval and the vegetation density. This relation can be described as…”

Section: Satellite Surface Soil Moisture Assimilationmentioning

confidence: 99%

See 1 more Smart Citation

Global land-surface evaporation estimated from satellite-based observations

Miralles¹,

Holmes

Jeu³

et al. 2011

Hydrol. Earth Syst. Sci.

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1,316

806

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Abstract. This paper outlines a new strategy to derive evaporation from satellite observations. The approach uses a variety of satellite-sensor products to estimate daily evaporation at a global scale and 0.25 degree spatial resolution. Central to this methodology is the use of the Priestley and Taylor (PT) evaporation model. The minimalistic PT equation combines a small number of inputs, the majority of which can be detected from space. This reduces the number of variables that need to be modelled. Key distinguishing features of the approach are the use of microwave-derived soil moisture, land surface temperature and vegetation density, as well as the detailed estimation of rainfall interception loss. The modelled evaporation is validated against one year of eddy covariance measurements from 43 stations. The estimated annual totals correlate well with the stations' annual cumulative evaporation (R = 0.80, N = 43) and present a low average bias (−5%). The validation of the daily time series at each individual station shows good model performance in all vegetation types and climate conditions with an average correlation coefficient of R = 0.83, still lower than the R = 0.90 found in the validation of the monthly time series. The first global map of annual evaporation developed through this methodology is also presented.

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Section: Satellite Surface Soil Moisture Assimilationmentioning

confidence: 99%

Section: Satellite Surface Soil Moisture Assimilationmentioning

confidence: 99%

Global land-surface evaporation estimated from satellite-based observations

Miralles¹,

Holmes

Jeu³

et al. 2011

Hydrol. Earth Syst. Sci.

Self Cite

1,316

806

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“…Total water storage estimates derived from missions like the Gravity Recovery and Climate Experiment [Tapley et al, 2004] provide a unique opportunity to observe initial catchment state over large areas in a way that can be combined with models [Van Dijk et al, 2011a]. Optical and passive and active microwave remote sensing can also help to improve model estimates of initial snow cover and shallow soil moisture state [Andreadis and Lettenmaier, 2006;de Jeu et al, 2008;Liu et al, 2012].…”

Section: Actual Forecast Skillmentioning

confidence: 99%

Global analysis of seasonal streamflow predictability using an ensemble prediction system and observations from 6192 small catchments worldwide

Dijk

Peña‐Arancibia

Wood

et al. 2013

Water Resources Research

138

107

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[1] Ideally, a seasonal streamflow forecasting system would ingest skilful climate forecasts and propagate these through calibrated hydrological models initialized with observed catchment conditions. At global scale, practical problems exist in each of these aspects. For the first time, we analyzed theoretical and actual skill in bimonthly streamflow forecasts from a global ensemble streamflow prediction (ESP) system. Forecasts were generated six times per year for 1979-2008 by an initialized hydrological model and an ensemble of 1 resolution daily climate estimates for the preceding 30 years. A post-ESP conditional sampling method was applied to 2.6% of forecasts, based on predictive relationships between precipitation and 1 of 21 climate indices prior to the forecast date. Theoretical skill was assessed against a reference run with historic forcing. Actual skill was assessed against streamflow records for 6192 small (<10,000 km 2 ) catchments worldwide. The results show that initial catchment conditions provide the main source of skill. Post-ESP sampling enhanced skill in equatorial South America and Southeast Asia, particularly in terms of tercile probability skill, due to the persistence and influence of the El Niño Southern Oscillation. Actual skill was on average 54% of theoretical skill but considerably more for selected regions and times of year. The realized fraction of the theoretical skill probably depended primarily on the quality of precipitation estimates. Forecast skill could be predicted as the product of theoretical skill and historic model performance. Increases in seasonal forecast skill are likely to require improvement in the observation of precipitation and initial hydrological conditions. Citation: van Dijk, A. I. J. M., J. L. Peña-Arancibia, E. F. Wood, J. Sheffield, and H. E. Beck (2013), Global analysis of seasonal streamflow predictability using an ensemble prediction system and observations from 6192 small catchments worldwide, Water Resour.

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“…Advances and new developments in monitoring of soil moisture (de Jeu et al 2008;Liu et al 2009), precipitation, andevapotranspiration (Anderson andKustas 2008;Kalma et al 2008) provide crucial elements to help constrain space-time trends in groundwater recharge. Future research will undoubtedly focus on the further integration of these multi-platform and multi-parameter observations, including GRACE data, in extensive hydrological models.…”

Section: Remote Sensing Of Space-time Trendsmentioning

confidence: 99%

Linking Climate Change and Groundwater

Green

2016

Integrated Groundwater Management

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Projected global change includes groundwater systems, which are linked with changes in climate over space and time. Consequently, global change affects key aspects of subsurface hydrology (including soil water, deeper vadose zone water, and unconfined and confined aquifer waters), surface-groundwater interactions, and water quality. Research and publications addressing projected climate effects on subsurface water are catching up with surface water studies. Even so, technological advances, new insights and understanding are needed regarding terrestrial-subsurface systems, biophysical process interactions, and feedbacks to atmospheric processes. Importantly, groundwater resources need to be assessed in the context of atmospheric CO 2 enrichment, warming trends and associated changes in intensities and frequencies of wet and dry periods, even though projections in space and time are uncertain. Potential feedbacks of groundwater on the global climate system are largely unknown, but may be stronger than previously assumed. Groundwater has been depleted in many regions, but management of subsurface storage remains an important option to meet the combined demands of agriculture, industry (particularly the energy sector), municipal and domestic water supply, and ecosystems. In many regions, groundwater is central to the water-food-energy-climate nexus. Strategic adaptation to global change must include flexible, integrated groundwater management over many decades. Adaptation itself must be adaptive over time. Further research is needed to improve our understanding of climate and groundwater interactions and to guide integrated groundwater management.

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Global Soil Moisture Patterns Observed by Space Borne Microwave Radiometers and Scatterometers

Cited by 330 publications

References 66 publications

Global land-surface evaporation estimated from satellite-based observations

Global land-surface evaporation estimated from satellite-based observations

Global analysis of seasonal streamflow predictability using an ensemble prediction system and observations from 6192 small catchments worldwide

Linking Climate Change and Groundwater

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