FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2767496663> ?p ?o ?g. }

• W2767496663 endingPage "228" @default.
• W2767496663 startingPage "212" @default.
• W2767496663 abstract "Simulating hydrological processes within the (semi-)arid region of the Murray-Darling Basin (MDB), Australia, is very challenging specially during droughts. In this study, we investigate whether integrating remotely sensed terrestrial water storage changes (TWSC) from the Gravity Recovery And Climate Experiment (GRACE) mission into a global water resources and use model enables a more realistic representation of the basin hydrology during droughts. For our study, the WaterGAP Global Hydrology Model (WGHM), which simulates the impact of human water abstractions on surface water and groundwater storage, has been chosen for simulating compartmental water storages and river discharge during the so-called ‘Millennium Drought’ (2001–2009). In particular, we test the ability of a parameter calibration and data assimilation (C/DA) approach to introduce long-term trends into WGHM, which are poorly represented due to errors in forcing, model structure and calibration. For the first time, the impact of the parameter equifinality problem on the C/DA results is evaluated. We also investigate the influence of selecting a specific GRACE data product and filtering method on the final C/DA results. Integrating GRACE data into WGHM does not only improve simulation of seasonality and trend of TWSC, but also it improves the simulation of individual water storage components. For example, after the C/DA, correlations between simulated groundwater storage changes and independent in-situ well data increase (up to 0.82) in three out of four sub-basins. Declining groundwater storage trends - found mainly in the south, i.e. Murray Basin, at in-situ wells - have been introduced while simulated soil water and surface water storage do not show trends, which is in agreement with existing literature. Although GRACE C/DA in MDB does not improve river discharge simulations, the correlation between river storage simulations and gauge-based river levels increases significantly from 0.15 to 0.52. By adapting the C/DA settings to the basin-specific characteristics and reducing the number of calibration parameters, their convergence is improved and their uncertainty is reduced. The time-variable parameter values resulting from C/DA allow WGHM to better react to the very wet Australian summer 2009/10. Using solutions from different GRACE data providers produces slightly different C/DA results. We conclude that a rigorous evaluation of GRACE errors is required to realistically account for the spread of the differences in the results." @default.
• W2767496663 created "2017-11-17" @default.
• W2767496663 creator A5026818785 @default.
• W2767496663 creator A5031787313 @default.
• W2767496663 creator A5060111105 @default.
• W2767496663 creator A5061320397 @default.
• W2767496663 creator A5069478919 @default.
• W2767496663 creator A5085388827 @default.
• W2767496663 creator A5088515517 @default.
• W2767496663 date "2018-01-01" @default.
• W2767496663 modified "2023-10-18" @default.
• W2767496663 title "Improving drought simulations within the Murray-Darling Basin by combined calibration/assimilation of GRACE data into the WaterGAP Global Hydrology Model" @default.
• W2767496663 cites W1544223462 @default.
• W2767496663 cites W1560979562 @default.
• W2767496663 cites W1584171125 @default.
• W2767496663 cites W1588827410 @default.
• W2767496663 cites W1698379769 @default.
• W2767496663 cites W1821979421 @default.
• W2767496663 cites W1867005924 @default.
• W2767496663 cites W1970438763 @default.
• W2767496663 cites W1978276928 @default.
• W2767496663 cites W1989839776 @default.
• W2767496663 cites W1990931465 @default.
• W2767496663 cites W2003991852 @default.
• W2767496663 cites W2010688508 @default.
• W2767496663 cites W2030832752 @default.
• W2767496663 cites W2031208576 @default.
• W2767496663 cites W2031346902 @default.
• W2767496663 cites W2033894107 @default.
• W2767496663 cites W2045752949 @default.
• W2767496663 cites W2053926920 @default.
• W2767496663 cites W2056539143 @default.
• W2767496663 cites W2061903993 @default.
• W2767496663 cites W2096391357 @default.
• W2767496663 cites W2114721961 @default.
• W2767496663 cites W2119132330 @default.
• W2767496663 cites W2122154990 @default.
• W2767496663 cites W2124076118 @default.
• W2767496663 cites W2130708243 @default.
• W2767496663 cites W2132012867 @default.
• W2767496663 cites W2143681587 @default.
• W2767496663 cites W2145122944 @default.
• W2767496663 cites W2151329188 @default.
• W2767496663 cites W2157098139 @default.
• W2767496663 cites W2158952405 @default.
• W2767496663 cites W2160057192 @default.
• W2767496663 cites W2161361143 @default.
• W2767496663 cites W2169875472 @default.
• W2767496663 cites W2170436314 @default.
• W2767496663 cites W2170607573 @default.
• W2767496663 cites W2179860363 @default.
• W2767496663 cites W2237141398 @default.
• W2767496663 cites W2280460489 @default.
• W2767496663 cites W2291987999 @default.
• W2767496663 cites W2324101356 @default.
• W2767496663 cites W2558276301 @default.
• W2767496663 cites W2585273472 @default.
• W2767496663 cites W2731471398 @default.
• W2767496663 cites W2740761956 @default.
• W2767496663 cites W590422800 @default.
• W2767496663 doi "https://doi.org/10.1016/j.rse.2017.10.029" @default.
• W2767496663 hasPublicationYear "2018" @default.
• W2767496663 type Work @default.
• W2767496663 sameAs 2767496663 @default.
• W2767496663 citedByCount "83" @default.
• W2767496663 countsByYear W27674966632018 @default.
• W2767496663 countsByYear W27674966632019 @default.
• W2767496663 countsByYear W27674966632020 @default.
• W2767496663 countsByYear W27674966632021 @default.
• W2767496663 countsByYear W27674966632022 @default.
• W2767496663 countsByYear W27674966632023 @default.
• W2767496663 crossrefType "journal-article" @default.
• W2767496663 hasAuthorship W2767496663A5026818785 @default.
• W2767496663 hasAuthorship W2767496663A5031787313 @default.
• W2767496663 hasAuthorship W2767496663A5060111105 @default.
• W2767496663 hasAuthorship W2767496663A5061320397 @default.
• W2767496663 hasAuthorship W2767496663A5069478919 @default.
• W2767496663 hasAuthorship W2767496663A5085388827 @default.
• W2767496663 hasAuthorship W2767496663A5088515517 @default.
• W2767496663 hasBestOaLocation W27674966632 @default.
• W2767496663 hasConcept C109007969 @default.
• W2767496663 hasConcept C114793014 @default.
• W2767496663 hasConcept C126197015 @default.
• W2767496663 hasConcept C126645576 @default.
• W2767496663 hasConcept C127313418 @default.
• W2767496663 hasConcept C151730666 @default.
• W2767496663 hasConcept C153294291 @default.
• W2767496663 hasConcept C153823671 @default.
• W2767496663 hasConcept C154945302 @default.
• W2767496663 hasConcept C183030095 @default.
• W2767496663 hasConcept C187320778 @default.
• W2767496663 hasConcept C18903297 @default.
• W2767496663 hasConcept C197115733 @default.
• W2767496663 hasConcept C201289731 @default.
• W2767496663 hasConcept C205649164 @default.
• W2767496663 hasConcept C24552861 @default.
• W2767496663 hasConcept C2776182401 @default.
• W2767496663 hasConcept C39432304 @default.

• next