Greater Water Surface Variability Revealed by New Congo River Field Data: Implications for Satellite Altimetry Measurements of Large Rivers

Carr, Andrew B.; Trigg, Mark A.; Tshimanga, Raphael M.; Borman, Duncan; Smith, Mark W.

doi:10.1029/2019gl083720

Cited by 35 publications

(14 citation statements)

References 35 publications

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“…Therefore, for the period 2000 to 2012, we estimated that the Cuvette Centrale retained over 23 megatons of material or 75% of the sediment fluxes from 70% of the basin area above Brazzaville/Kinshasa (combined contributing areas of stations 1 to 8). The low velocities observed in this area of the wetlands [83,91] 2021) analysed the water balance of the Cuvette Centrale and verified its role as a sponge or buffer that accumulates water in the rainy season and releases it in the dry season. A running hypothesis suggests that this may be the main means by which supplies-if any-of suspended sediment is made to the main river [33] (Alsdorf et al, 2016).…”

Section: Sediment Balance In the Cuvette Centralementioning

confidence: 80%

“…Water surface slopes are higher here with a reduced velocity. This river stretch is multi-channel with constrictions that reduce the widths considerably [83] (Carr et al, 2019). The Kasai River then joins the main stem at Kwamouth.…”

Section: Additional Comparison Of the Model Simulations With Historical Datasetsmentioning

confidence: 99%

“…It is important to note also the Cuvette central area, although located on low slopes with low erodible soils, yield relatively high sediment within its tributaries because of their high content in organic matter, which are mostly made up of fine particles that are transported easily even at low velocities. The coarser particles, most likely from stream bank erosion, will travel only shorter distances and be deposited, helping to create anastomosing structures observed along the middle reach [83,87,88]…”

Section: Sediment Source Areasmentioning

confidence: 99%

“…(Laraque et al, 1998a;Carr et al, 2019) would ensure deposition takes place. This would imply a minimum exchange of material between the wetland and the main river.…”

mentioning

confidence: 99%

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Sediment Balance Estimation of the ‘Cuvette Centrale’ of the Congo River Basin Using the SWAT Hydrological Model

Datok

Sauvage

Fabre

et al. 2021

Water

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In this study, the SWAT hydrological model was used to estimate the sediment yields in the principal drainage basins of the Congo River Basin. The model was run for the 2000–2012 period and calibrated using measured values obtained at the basins principal gauging station that controls 98% of the basin area. Sediment yield rates of 4.01, 5.91, 7.88 and 8.68 t km−2 yr−1 were estimated for the areas upstream of the Ubangi at Bangui, Sangha at Ouesso, Lualaba at Kisangani, and Kasai at Kuto-Moke, respectively—the first three of which supply the Cuvette Centrale. The loads contributed into the Cuvette Centrale by eight tributaries were estimated to be worth 0.04, 0.07, 0.09, 0.18, 0.94, 1.50, 1.60, and 26.98 × 106 t yr−1 from the Likouala Mossaka at Makoua, Likouala aux Herbes at Botouali, Kouyou at Linnegue, Alima at Tchikapika, Sangha at Ouesso, Ubangi at Mongoumba, Ruki at Bokuma and Congo at Mbandaka, respectively. The upper Congo supplies up to 85% of the fluxes in the Cuvette Centrale, with the Ubangi and the Ruki contributing approximately 5% each. The Cuvette Centrale acts like a big sink trapping up to 23 megatons of sediment produced upstream (75%) annually.

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Section: Sediment Balance In the Cuvette Centralementioning

confidence: 80%

Section: Additional Comparison Of the Model Simulations With Historical Datasetsmentioning

confidence: 99%

Section: Sediment Source Areasmentioning

confidence: 99%

“…(Laraque et al, 1998a;Carr et al, 2019) would ensure deposition takes place. This would imply a minimum exchange of material between the wetland and the main river.…”

mentioning

confidence: 99%

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Sediment Balance Estimation of the ‘Cuvette Centrale’ of the Congo River Basin Using the SWAT Hydrological Model

Datok

Sauvage

Fabre

et al. 2021

Water

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“…Therefore, the large size of the basin, its spatial heterogeneity and the lack of in situ observations have made difficult the validation of long-term satellite-derived observations of surface hydrology components and 120 the proper set-up of large-scale hydrological models (Munzimi et al, 2019). Recent results call for the need of a comprehensive spatial coverage of CRB water surface elevation using satellite altimetry-derived observation to encompass the full range of variability across its rivers and wetlands up to its outlet (Carr et al, 2019). Additionally, even if recent efforts have been characterizing how water flows across the CRB, the basin-scale dynamics is still understudied, especially regarding the contributions of the different sub -basins to the entire basin hydrology (Alsdorf 125 et al, 2016;Laraque et al, 2020) and to the annual bimodal pattern in the CRB river discharge near to its mouth.…”

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confidence: 99%

A combined use of in situ and satellite-derived observations to characterize surface hydrology and its variability in the Congo River Basin

Kitambo

Papa

Paris

et al. 2021

Preprint

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Abstract. The Congo River Basin (CRB) is the second largest river system in the world, but its hydroclimatic characteristics remain relatively poorly known. Here, we jointly analyze a large record of in situ and satellite-derived observations, including long term time series of Surface Water Height (SWH) from radar altimetry (a total of 2,311 virtual stations) and surface water extent (SWE) from a multi-satellite technique to better characterize CRB surface hydrology and its variability. Firstly, we show that SWH from radar altimetry multi-missions agree well with in situ water stage at various locations, with root mean square deviation varying from 10 cm (with Sentinel-3A) to 75 cm (with European Remote Sensing-2). SWE from multi-satellite observations also shows a good behavior over a ~25-year period against in situ observations from sub-basin to basin scale. Both datasets help to better characterize the large spatial and temporal variability of hydrological patterns across the basin, with SWH exhibiting annual amplitude of more than 5 m in the northern sub-basins while Congo main-stream and Cuvette Centrale tributaries vary in smaller proportions (1.5 m to 4.5 m). Furthermore, SWH and SWE help better illustrate the spatial distribution and different timings of the CRB annual flood dynamic and how each sub-basin and tributary contribute to the hydrological regime at the outlet of the basin (the Brazzaville/Kinshasa station), including its peculiar bi-modal pattern. Across the basin, we jointly use SWH and SWE to estimate time lag and water travel time to reach the Brazzaville/Kinshasa station, ranging from 0–1 month in its vicinity downstream the basin up to 3 months in remote areas and small tributaries. Northern sub-basins and the central Congo region highly contribute to the large peak in December–January while the southern part of the basin supplies water to both hydrological peaks, in particular to the moderate one in April–May. The results are supported using in situ observations at various locations in the basin. Our results contribute to a better characterization of the hydrological variability in the CRB and represent an unprecedented source of information for hydrological modeling and to study hydrological processes over the region.

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Two Decades of Hydrologic Modeling and Predictions in the Congo River Basin

Tshimanga

2022

Congo Basin Hydrology, Climate, and Biogeochemistry

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Greater Water Surface Variability Revealed by New Congo River Field Data: Implications for Satellite Altimetry Measurements of Large Rivers

Cited by 35 publications

References 35 publications

Sediment Balance Estimation of the ‘Cuvette Centrale’ of the Congo River Basin Using the SWAT Hydrological Model

Sediment Balance Estimation of the ‘Cuvette Centrale’ of the Congo River Basin Using the SWAT Hydrological Model

A combined use of in situ and satellite-derived observations to characterize surface hydrology and its variability in the Congo River Basin

Two Decades of Hydrologic Modeling and Predictions in the Congo River Basin

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