Global patterns in base flow index and recession based on streamflow observations from 3394 catchments

Beck, Hylke E.; Dijk, Albert I. J. M. van; Miralles, Diego G.; Jeu, R. A. M. de; Bruijnzeel, L. A.; McVicar, Tim R.; Schellekens, Jaap

doi:10.1002/2013wr013918

Cited by 237 publications

(259 citation statements)

References 121 publications

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“…Since the base flow index shows the ratio between groundwater flows and total streamflow, it is comparable to the parameter PSUB. The value of 0.6 for PSUB matches the calculated base flow index for the studied region as part of the Global Streamflow Characteristics Dataset (GSCD) [20], which was 0.597, quite well. The calculated FDC is shown in Figure 7.…”

Section: Lumped Rainfall-runoff Methodssupporting

confidence: 61%

Derivation of Flow Duration Curves to Estimate Hydropower Generation Potential in Data-Scarce Regions

Reichl

Hack

2017

Water

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Small-scale hydropower is a robust and reliable form of sustainable energy supply in remote areas. On the one hand, the potential for hydropower generation depends on the specific climate in a given place, and precipitation above all. On the other hand, such potential also depends on the catchment's characteristics, e.g., topography, land use, and soils. In the absence of discharge measurements, the available river flow for hydropower production can be estimated in the form of a flow duration curve based on these variables. In this study, the lumped rainfall-runoff method by Crawford and Thurin (1981) was modified to calculate a flow duration curve with a daily time step for an ungauged catchment in Nicaragua. Satisfactory results could be obtained by calibrating the method with the aid of a few discharge measurements. Best results were obtained with a parameter set for groundwater flow and recharge to groundwater from excess soil moisture of 0.014 and 0.6, respectively. Considering the climate and catchment characteristics of the study site, this parameterization can be physically reasoned.

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Section: Lumped Rainfall-runoff Methodssupporting

confidence: 61%

Derivation of Flow Duration Curves to Estimate Hydropower Generation Potential in Data-Scarce Regions

Reichl

Hack

2017

Water

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“…Other studies investigated how recession parameters a and b change with geology (Tague and Grant, 2004), scale (Clark et al, 2009), andclimate (van Dijk, 2010) or combinations thereof (Farmer et al, 2003;Beck et al, 2013;McMillan et al, 2014). At least for some catchments recession intercept a appears to vary throughout the year, in response to catchment-scale water storage in conjunction with spatial heterogeneity (Shaw and Riha, 2012;Shaw et al, 2013;Lyon et al, 2015).…”

Section: Physical Interpretationmentioning

confidence: 99%

Streamflow recession patterns can help unravel the role of climate and humans in landscape co-evolution

Bogaart

Velde²,

Lyon

et al. 2016

Hydrol. Earth Syst. Sci.

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Abstract. Traditionally, long-term predictions of river discharges and their extremes include constant relationships between landscape properties and model parameters. However, due to the co-evolution of many landscape properties more sophisticated methods are necessary to quantify future landscape-hydrological model relationships. As a first step towards such an approach we use the Brutsaert and Nieber (1977) analysis method to characterize streamflow recession behaviour of ≈ 200 Swedish catchments within the context of global change and landscape co-evolution. Results suggest that the Brutsaert-Nieber parameters are strongly linked to the climate, soil, land use, and their interdependencies. Many catchments show a trend towards more non-linear behaviour, meaning not only faster initial recession but also slower recession towards base flow. This trend has been found to be independent from climate change. Instead, we suggest that land cover change, both natural (restoration of natural soil profiles in forested areas) and anthropogenic (reforestation and optimized water management), is probably responsible. Both change types are characterised by system adaptation and change, towards more optimal ecohydrological conditions, suggesting landscape co-evolution is at play. Given the observed magnitudes of recession changes during the past 50 years, predictions of future river discharge critically need to include the effects of landscape co-evolution. The interconnections between the controls of land cover and climate on river recession behaviour, as we have quantified in this paper, provide first-order handles to do so.

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“…Although precipitation intensity controlled runoff-generating processes that can be observed during periods of rainfall [Dunne, 1983], for many catchments subsurface water storage is for the majority of time the main driver of streamflow response [Spence, 2010;McNamara et al, 2011;Riegger and Tourian, 2014]. There are regional differences in the estimated volume and timescale of the subsurface contributions to streamflow [Beck et al, 2013]. Both climatic changes and variations, and human groundwater abstractions are affecting groundwater storage around the globe [Green et al, 2011;Taylor et al, 2013;Döll et al, 2014;Richey et al, 2015;Gleeson et al, 2015], but a theory that exposes the sensitivity of flow to storage changes across diverse landscapes and spatial scales is currently not exploited.…”

Section: Introductionmentioning

confidence: 99%

Streamflow sensitivity to water storage changes across Europe

Berghuijs

Hartmann

Woods

2016

Geophysical Research Letters

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Terrestrial water storage is the primary source of river flow. We introduce storage sensitivity of streamflow (ϵS), which for a given flow rate indicates the relative change in streamflow per change in catchment water storage. ϵS can be directly derived from streamflow observations. Analysis of 725 catchments in Europe reveals that ϵS is high in, e.g., parts of Spain, England, Germany, and Denmark, whereas flow regimes in parts of the Alps are more resilient (that is, less sensitive) to storage changes. A regional comparison of ϵS with observations indicates that ϵS is significantly correlated with variability of low (R2 = 0.41), median (R2 = 0.27), and high flow conditions (R2 = 0.35). Streamflow sensitivity provides new guidance for a changing hydrosphere where groundwater abstraction and climatic changes are altering water storage and flow regimes.

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Global patterns in base flow index and recession based on streamflow observations from 3394 catchments

Cited by 237 publications

References 121 publications

Derivation of Flow Duration Curves to Estimate Hydropower Generation Potential in Data-Scarce Regions

Derivation of Flow Duration Curves to Estimate Hydropower Generation Potential in Data-Scarce Regions

Streamflow recession patterns can help unravel the role of climate and humans in landscape co-evolution

Streamflow sensitivity to water storage changes across Europe

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