Forests and floods: A new paradigm sheds light on age‐old controversies

Alila, Younes; Kuraś, Piotr K.; Schnorbus, M.; Hudson, Robert O.

doi:10.1029/2008wr007207

Cited by 158 publications

(218 citation statements)

References 186 publications

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“…Assuming that the drivers included in the models can explain a large part of the natural variability of flow peaks, the detected change in the urbanizing catchment can be attributable solely to the increasing urban cover, in particular when compared to the unchanged patterns in the high flows of the rural paired catchment. Paired catchments have been widely employed in the assessment of the effects of changes in the catchment vegetation on river flow, in particular in forest hydrology [Brown et al, 2005;Alila et al, 2009]. In this study, the effects of the changes in land use on peak flows are investigated by assessing if any changes can be identified in the observed peak flows of the paired catchments.…”

Section: Introductionmentioning

confidence: 99%

Detection and attribution of urbanization effect on flood extremes using nonstationary flood‐frequency models

Prosdocimi

Kjeldsen

Miller

2015

Water Resources Research

177

111

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This study investigates whether long-term changes in observed series of high flows can be attributed to changes in land use via nonstationary flood-frequency analyses. A point process characterization of threshold exceedances is used, which allows for direct inclusion of covariates in the model; as well as a nonstationary model for block maxima series. In particular, changes in annual, winter, and summer block maxima and peaks over threshold extracted from gauged instantaneous flows records in two hydrologically similar catchments located in proximity to one another in northern England are investigated. The study catchment is characterized by large increases in urbanization levels in recent decades, while the paired control catchment has remained undeveloped during the study period . To avoid the potential confounding effect of natural variability, a covariate which summarizes key climatological properties is included in the flood-frequency model. A significant effect of the increasing urbanization levels on high flows is detected, in particular in the summer season. Point process models appear to be superior to block maxima models in their ability to detect the effect of the increase in urbanization levels on high flows.

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Section: Introductionmentioning

confidence: 99%

Detection and attribution of urbanization effect on flood extremes using nonstationary flood‐frequency models

Prosdocimi

Kjeldsen

Miller

2015

Water Resources Research

177

111

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“…The paired-catchment approach was applied to examine the effect of thinning on peak flow based on an assumption that rainfall and runoff responses between treatment and control catchments remained consistent during the pre-and post-thinning periods. Because the catchments were small (< 1 ha), storm events in control and treated catchment were similar in time, duration, intensity, or spatial extent (Alila et al, 2009). Additionally, the dominant internal hydrological processes were similar between the two catchments and remained consistent before and after treatments Dung et al, 2012).…”

Section: Hydrograph Analysismentioning

confidence: 95%

“…Analyzing the same data set, Thomas and Megahan (1998) demonstrated that peak runoff did not increase in large basins, but peak runoff in small basins increased 2-fold when comparing pre-and postharvesting periods. Reanalysis of these data were also conducted by Beschta et al (2000) and Alila et al (2009) to try to clarify these effects.…”

Section: Introductionmentioning

confidence: 99%

Peak flow responses and recession flow characteristics after thinning of Japanese cypress forest in a headwater catchment

Dung

Gomi

Miyata

et al. 2012

Hydrological Research Letters

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“…Reducing local flooding risk by increased drainage increases flooding risk downstream, challenging the nested-scales management of watersheds to find an optimal spatial distribution, rather than minimisation, of flooding probabilities. Well-studied effects of forest conversion on peak flows in small upper stream catchments (Bruijnzeel, 2004;Alila et al, 2009) do not necessarily translate to flooding downstream. With most of the published studies still referring to the temperate zone, the situation in the tropics (generally in the absence of snow) is contested (Bonell and Bruijnzeel, 2005).…”

Section: Introductionmentioning

confidence: 99%

“…The statistical challenges of attribution of cause and effect in such data sets are considerable with land use/land cover effects interacting with spatially and temporally variable rainfall, geological configuration and the fact that land use is not changing in random fashion or following any pre-randomised design (Alila et al, 2009;Rudel et al, 2005). Hydrological analysis across 12 catchments in Puerto Rico by Beck et al (2013) did not find significant relationships between the change in forest cover or urban area, and change in various flow characteristics, despite indications that regrowing forests increased evapotranspiration.…”

Section: Introductionmentioning

confidence: 99%

Flood risk reduction and flow buffering as ecosystem services – Part 1: Theory on flow persistence, flashiness and base flow

Noordwijk

Tanika²,

Lusiana³

2017

Hydrol. Earth Syst. Sci.

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Abstract. Flood damage reflects insufficient adaptation of human presence and activity to location and variability of river flow in a given climate. Flood risk increases when landscapes degrade, counteracted or aggravated by engineering solutions. Efforts to maintain and restore buffering as an ecosystem function may help adaptation to climate change, but this require quantification of effectiveness in their specific social-ecological context. However, the specific role of forests, trees, soil and drainage pathways in flow buffering, given geology, land form and climate, remains controversial. When complementing the scarce heavily instrumented catchments with reliable long-term data, especially in the tropics, there is a need for metrics for data-sparse conditions. We present and discuss a flow persistence metric that relates transmission to river flow of peak rainfall events to the base-flow component of the water balance. The dimensionless flow persistence parameter F p is defined in a recursive flow model and can be estimated from limited time series of observed daily flow, without requiring knowledge of spatially distributed rainfall upstream. The F p metric (or its change over time from what appears to be the local norm) matches local knowledge concepts. Inter-annual variation in the F p metric in sample watersheds correlates with variation in the "flashiness index" used in existing watershed health monitoring programmes, but the relationship between these metrics varies with context. Inter-annual variation in F p also correlates with common base-flow indicators, but again in a way that varies between watersheds. Further exploration of the responsiveness of F p in watersheds with different characteristics to the interaction of land cover and the specific realisation of space-time patterns of rainfall in a limited observation period is needed to evaluate interpretation of F p as an indicator of anthropogenic changes in watershed conditions.

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Forests and floods: A new paradigm sheds light on age‐old controversies

Cited by 158 publications

References 186 publications

Detection and attribution of urbanization effect on flood extremes using nonstationary flood‐frequency models

Detection and attribution of urbanization effect on flood extremes using nonstationary flood‐frequency models

Peak flow responses and recession flow characteristics after thinning of Japanese cypress forest in a headwater catchment

Flood risk reduction and flow buffering as ecosystem services – Part 1: Theory on flow persistence, flashiness and base flow

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