Hydrological Tracking Model for Amazon Surface Waters

Sorribas, Mino Viana; Paiva, Rodrigo Cauduro Dias de; Fleischmann, Ayan Santos; Collischonn, Walter

doi:10.1029/2019wr024721

Cited by 16 publications

(21 citation statements)

References 105 publications

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“…P drives R season over the upstream sub-basins with a time lag of 1-2 months between P and R. Over northern and central sub-basins, dS becomes negative while R is still increasing (and reaches its maximum 2 months later). This illustrates the floodplain buffer effect that charged water before releasing it into the river (Sorribas et al, 2020). E seasonal variation is weaker than for P but E peak seems to be in phase with P over southern basin arguing for a water-limited behavior (Espinoza PELLET ET AL.…”

Section: Sawc Evaluationmentioning

confidence: 93%

“…Over northern and central sub‐basins, dS becomes negative while R is still increasing (and reaches its maximum 2 months later). This illustrates the floodplain buffer effect that charged water before releasing it into the river (Sorribas et al., 2020). E seasonal variation is weaker than for P but E peak seems to be in phase with P over southern basin arguing for a water‐limited behavior (Espinoza et al., 2019; Sörensson & Ruscica, 2018) while E peak follows P minimum month in northern basin depicting energy‐limited system (Espinoza et al., 2019).…”

Section: Satellite Water Cycle Assessmentmentioning

confidence: 95%

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Coherent Satellite Monitoring of the Water Cycle Over the Amazon. Part 1: Methodology and Initial Evaluation

Pellet

Aires

Yamazaki

et al. 2021

Water Resources Research

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The Amazon is the largest drainage basin on Earth, with a total area of 6.10 6 km 2 (excluding Tocantins basin), and supplies 15%-20% of global freshwater input to the ocean. The average discharge at the most downstream gauging station Obidos is ≃ 120 ⋅ 10 3 m 3 ⋅s −1 in December to ≃300 ⋅ 10 3 m 3 ⋅s −1 in May (Moura et al., 2016;Ward et al., 2015) while the Tapajós and Xingu tributaries contributed an additional 17 ⋅ 10 3 m 3 s −1 in average to the total discharge of the Amazon River downstream of Obidos.The Amazon region is currently facing risks due to climate variability and change, as well as increased anthropogenic pressures (

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Section: Sawc Evaluationmentioning

confidence: 93%

Section: Satellite Water Cycle Assessmentmentioning

confidence: 95%

Coherent Satellite Monitoring of the Water Cycle Over the Amazon. Part 1: Methodology and Initial Evaluation

Pellet

Aires

Yamazaki

et al. 2021

Water Resources Research

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“…Sorribas et al. (2020) used particle tracking methods to estimate surface water travel times along the Amazon basin as 45 days (median), with 20% of Amazon River waters flowing through floodplains (Figure 11c). While basin‐scale applications have employed 1D models (longitudinal direction along rivers), the necessity of representing the 2D diffuse flow in floodplains, especially during receding waters, was highlighted by Alsdorf et al.…”

Section: Integrative and Interdisciplinary Studiesmentioning

confidence: 99%

Amazon Hydrology From Space: Scientific Advances and Future Challenges

Fassoni‐Andrade

Fleischmann

Papa

et al. 2021

Reviews of Geophysics

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As the largest river basin on Earth, the Amazon is of major importance to the world's climate and water resources. Over the past decades, advances in satellite‐based remote sensing (RS) have brought our understanding of its terrestrial water cycle and the associated hydrological processes to a new era. Here, we review major studies and the various techniques using satellite RS in the Amazon. We show how RS played a major role in supporting new research and key findings regarding the Amazon water cycle, and how the region became a laboratory for groundbreaking investigations of new satellite retrievals and analyses. At the basin‐scale, the understanding of several hydrological processes was only possible with the advent of RS observations, such as the characterization of "rainfall hotspots" in the Andes‐Amazon transition, evapotranspiration rates, and variations of surface waters and groundwater storage. These results strongly contribute to the recent advances of hydrological models and to our new understanding of the Amazon water budget and aquatic environments. In the context of upcoming hydrology‐oriented satellite missions, which will offer the opportunity for new synergies and new observations with finer space‐time resolution, this review aims to guide future research agenda toward integrated monitoring and understanding of the Amazon water from space. Integrated multidisciplinary studies, fostered by international collaborations, set up future directions to tackle the great challenges the Amazon is currently facing, from climate change to increased anthropogenic pressure.

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“…Alsdorf et al (2010) Using numerical models∼20% of Amazon's flow passes through large floodplainsSorribas et al (2020) Upper limits of flow onto the floodplain at 200% of peak channel discharge & flow back into the channel at 40% of peak channel discharge daPaz et al (2011) …”

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confidence: 99%

An Integrative Conceptualization of Floodplain Storage

Wohl

2021

Reviews of Geophysics

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Floodplains perform diverse functions, including attenuation of fluxes of water, solutes, and particulate material. Critical details of floodplain storage including magnitude, duration, and spatial distribution are strongly influenced by floodplain biogeochemical processes and biotic communities. Floodplain storage of diverse materials can be conceptualized in the form of a budget that quantifies inputs, outputs, and storage within the floodplain control volume. The floodplain control volume is here defined as bounded on the inner edges by the banks of the active channel(s), on the outer edges by the limit of periodic flooding and the deposition of fluvially transported sediment, on the underside by the extent of hyporheic exchange flows and the floodplain aquifer, and on the upper side by the upper elevation of living vegetation. Fluxes within the floodplain control volume can also change the location, characteristics, and residence time of material in storage. Fluxes, residence time, and quantities of material stored in floodplains can be measured directly; inferred from diverse types of remotely sensed data; or quantitatively estimated using numerical models. Human activities can modify floodplain storage by: hydrologically and/or geomorphically disconnecting channels and floodplains; altering fluxes of water and sediment to the river corridor; and obliterating floodplains through alluvial mining or urbanization. Floodplain restoration can focus on enlarging the functional floodplain, reconnecting the channel and floodplain, restoring natural regimes of water, sediment, and/or large wood, or enhancing the spatial heterogeneity of the channel and floodplain. Each form of floodplain restoration can increase floodplain storage and resilience to disturbances.

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Hydrological Tracking Model for Amazon Surface Waters

Cited by 16 publications

References 105 publications

Coherent Satellite Monitoring of the Water Cycle Over the Amazon. Part 1: Methodology and Initial Evaluation

Coherent Satellite Monitoring of the Water Cycle Over the Amazon. Part 1: Methodology and Initial Evaluation

Amazon Hydrology From Space: Scientific Advances and Future Challenges

An Integrative Conceptualization of Floodplain Storage

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