The spatio-temporal variability of groundwater storage in the Amazon River Basin

Frappart, Frédéric; Papa, Fabrice; Güntner, Andreas; Tomasella, Javier; Pfeffer, Julia; Ramillien, Guillaume; Vilanova, Emilio; Schietti, Juliana; Seoane, Lucía; Carvalho, João da Silva; Moreira, Daniel Medéiros; Bonnet, Marie‐Paule; Seyler, Frédérique

doi:10.1016/j.advwatres.2018.12.005

Cited by 62 publications

(67 citation statements)

References 68 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Uncertainties of this study. The decomposition technique employed in the present study to estimate groundwater is commonly used (see the review from Frappart & Ramillien 64 on GRACE and groundwater for instance), and several specific regional studies proved that it is a powerful tool [68][69][70] . Following Frappart et al 69 , the uncertainty on groundwater storage variations can be computed as follows: Based on Ramillien et al 71 , we assumed that σ TWS < 0.015 m over semi-arid area.…”

Section: Methodsmentioning

confidence: 99%

“…The decomposition technique employed in the present study to estimate groundwater is commonly used (see the review from Frappart & Ramillien 64 on GRACE and groundwater for instance), and several specific regional studies proved that it is a powerful tool [68][69][70] . Following Frappart et al 69 , the uncertainty on groundwater storage variations can be computed as follows: Based on Ramillien et al 71 , we assumed that σ TWS < 0.015 m over semi-arid area. Based on Frappart et al 68 and Papa et al 70 , we assumed that: σ SWS < max(△h)σ Sf lood + max(S f lood )σ h Over Chad Lake, the maximum change of water level from one month to another (max(△h)) is 0.15 m, the maximum surface of the lake during the observation period (max(△Sf lood)) is 16,800 km 2 , the associated maximum error (σ Sf lood ) is 8.5 of this latter value, the maximum error on the water level is assumed to 0.03 m (see Birkett, 2000 14 ).…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

The Lake Chad hydrology under current climate change

Pham-Duc

Sylvestre

Papa

et al. 2020

Sci Rep

104

View full text Add to dashboard Cite

Lake Chad, in the Sahelian zone of west-central Africa, provides food and water to ~50 million people and supports unique ecosystems and biodiversity. In the past decades, it became a symbol of current climate change, held up by its dramatic shrinkage in the 1980s. Despites a partial recovery in response to increased Sahelian precipitation in the 1990s, Lake Chad is still facing major threats and its contemporary variability under climate change remains highly uncertain. Here, using a new multi-satellite approach, we show that Lake Chad extent has remained stable during the last two decades, despite a slight decrease of its northern pool. Moreover, since the 2000s, groundwater, which contributes to ~70% of Lake Chad’s annual water storage change, is increasing due to water supply provided by its two main tributaries. Our results indicate that in tandem with groundwater and tropical origin of water supply, over the last two decades, Lake Chad is not shrinking and recovers seasonally its surface water extent and volume. This study provides a robust regional understanding of current hydrology and changes in the Lake Chad region, giving a basis for developing future climate adaptation strategies.

show abstract

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

The Lake Chad hydrology under current climate change

Pham-Duc

Sylvestre

Papa

et al. 2020

Sci Rep

104

View full text Add to dashboard Cite

show abstract

“…In terms of relationships, Guyot et al [14] found that water discharge and solid fluxes were related, but relationships between rainfall and discharge with sediment load have not been further assessed in this Andean sub-basin. Recent studies [15,16] have determined that groundwater is a significant contributor to the water discharge in many Amazon headwater sub-basins and could influence sediment concentrations as well.…”

Section: Introductionmentioning

confidence: 99%

On the Relationship between Suspended Sediment Concentration, Rainfall Variability and Groundwater: An Empirical and Probabilistic Analysis for the Andean Beni River, Bolivia (2003–2016)

Rivera

Poduje

Molina

et al. 2019

Water

View full text Add to dashboard Cite

Fluvial sediment dynamics plays a key role in the Amazonian environment, with most of the sediments originating in the Andes. The Madeira River, the second largest tributary of the Amazon River, contributes up to 50% of its sediment discharge to the Atlantic Ocean, most of it provided by the Andean part of the Madeira basin, in particular the Beni River. In this study, we assessed the rainfall (R)-surface suspended sediment concentration (SSSC) and discharge (Q)-SSSC relationship at the Rurrenabaque station (200 m a.s.l.) in the Beni Andean piedmont (Bolivia). We started by showing how the R and Q relationship varies throughout the hydrological year (September to August), describing a counter-clockwise hysteresis, and went on to evaluate the R–SSSC and Q–SSSC relationships. Although no marked hysteresis is observed in the first case, a clockwise hysteresis is described in the second. In spite of this, the rating curve normally used ( SSSC = aQ b ) shows a satisfactory R2 = 0.73 (p < 0.05). With regard to water discharge components, a linear function relates the direct surface flow Qs–SSSC, and a hysteresis is observed in the relationship between the base flow Qb and SSSC. A higher base flow index (Qb/Q) is related to lower SSSC and vice versa. This article highlights the role of base flow on sediment dynamics and provides a method to analyze it through a seasonal empirical model combining the influence of both Qb and Qs, which could be employed in other watersheds. A probabilistic method to examine the SSSC relationship with R and Q is also proposed.

show abstract

“…In general, the SWE and SM can be simulated from hydrological models such as GLDAS, W3RA and WGHM, of which the GLDAS is the most commonly model. In recent years, there have been many studies of the retrieval of groundwater changes in different regions using the GRACE satellite gravity data and hydrological models, e.g., Mississippi River basin, the North China Plain, Amazon Basin [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Detection of groundwater storage variability based on GRACE and CABLE model in the Murray-Darling Basin

2019

View full text Add to dashboard Cite

Monitoring groundwater storage is in great importance for economic and social development. In this paper, the monthly GRACE data from 2003 to 2015 is combined with the Community Atmosphere Biosphere Land Exchange (CABLE) model to estimate the variations of groundwater storage (GWS) in the Murray-Darling Basin (MDB). The results show that (1) the simulations of TWS from CABLE are more accurate than GLDAS over the MDB, and there is a higher correlation coefficient of 0.94 and a lower RMSE of 15.74 between CABLE and GRACE. (3) The spatial pattern of GWS trends shows decline trends in the southwest, east and south, and increasing trends in the north and south central (3) For the whole MDB, the average GWS has strong seasonality and shows an increasing trend with a rate of 1.19 0.41 mmyyear between 2003 and 2015.

show abstract

The spatio-temporal variability of groundwater storage in the Amazon River Basin

Cited by 62 publications

References 68 publications

The Lake Chad hydrology under current climate change

The Lake Chad hydrology under current climate change

On the Relationship between Suspended Sediment Concentration, Rainfall Variability and Groundwater: An Empirical and Probabilistic Analysis for the Andean Beni River, Bolivia (2003–2016)

Detection of groundwater storage variability based on GRACE and CABLE model in the Murray-Darling Basin

Contact Info

Product

Resources

About