Use of Flood Seasonality in Pooling‐Group Formation and Quantile Estimation: An Application in Great Britain

Formetta, Giuseppe; Bell, V. A.; Stewart, Elizabeth

doi:10.1002/2017wr021623

Cited by 13 publications

(13 citation statements)

References 40 publications

(47 reference statements)

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“…The number of stations with at least 40 years of data varies from 60 to 65, depending on the rainfall duration (e.g., Figure a). Robson and Reed () used a minimum record length of 20 years for computing the PUM for floods regarding T = 20 and 50 years, Formetta, Bell, and Stewart () employed a minimum record length of 30 years when estimating quantiles for return periods from 5 to 100 years, whereas Mostofi Zadeh and Burn () used a minimum record length of 90 years for return periods from 2 to 100 years.…”

Section: Resultsmentioning

confidence: 99%

Pooled frequency analysis for intensity–duration–frequency curve estimation

Requena

Burn

Coulibaly

2019

Hydrological Processes

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Rainfall intensity–duration–frequency (IDF) curves are used in the design of urban infrastructure. Their estimation is based on rainfall frequency analysis, usually performed on rainfall records from a single gauged station. However, available at‐site record length is often too short to provide accurate estimates for long return periods. In the present study, a general framework for pooled rainfall frequency analysis based on the index‐event model is proposed for IDF estimation at gauged stations. Pooling group formation is defined by the region of influence approach on the basis of the geographical distance similarity measure. Several pooled approaches are defined and evaluated by a procedure through which quantile estimation and uncertainty are assessed. Alternate approaches for the definition of a pooling group are based on different criteria regarding initial pooling group size (and the relationship between size and return period), approaches for assessing pooling group homogeneity, and the use of macroregions in pooling group formation. The proposed framework is applied to identify the preferred approach for pooled rainfall intensity frequency analysis in Canada. Pooled approaches are found to provide more precise estimates than the at‐site approach, especially for long return periods. Pooled parent distribution selection supported the use of the generalized extreme value distribution across the country. Recommendations for pooling group formation include increasing the pooling group size with increases in return period and identifying an appropriate trade‐off between pooling group homogeneity and size for long return periods.

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Section: Resultsmentioning

confidence: 99%

Pooled frequency analysis for intensity–duration–frequency curve estimation

Requena

Burn

Coulibaly

2019

Hydrological Processes

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“…SUTRA simulates permafrost by incorporating the physics of water phase change, allowing for modeling of pore water freeze and thaw, and permeability variations with changing ice and water content, temperature-dependent variations in liquid water density, and the contribution of the latent heat of fusion to the subsurface energy balance. The freeze-thaw version of SUTRA has been used simulate groundwater flow and heat transport in a number of frozen ground studies (e.g., Briggs et al, 2014Briggs et al, , 2018Evans et al, 2018;Evans & Ge, 2017;Ge et al, 2011;Kurylyk et al, 2014Kurylyk et al, , 2016Lamontagne-Hallé et al, 2018;McKenzie & Voss, 2013;Walvoord et al, 2019;Wellman et al, 2013;Zipper et al, 2018) and has been benchmarked against other coupled cryohydrogeological models by Grenier et al (2018).…”

Section: Numerical Groundwater Flow and Heat Transport Modelmentioning

confidence: 99%

Water Tracks Enhance Water Flow Above Permafrost in Upland Arctic Alaska Hillslopes

et al. 2020

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Upland permafrost regions occupy approximately one third of the Arctic landscape. In upland regions, hydrologic fluxes are influenced by water tracks, curvilinear features on hillslopes that preferentially fill with and route water in response to snowmelt and rainfall when the soil above continuous permafrost thaws in the summer. As continued warming of the Arctic may alter hydrologic cycling leading to increased frequency of extreme hydrologic events like drought and flooding as well as modification of biogeochemical cycling, it is imperative to untangle the interplay between precipitation, runoff, and subsurface flow as water is routed from upland Arctic regions to the Arctic Ocean. This study quantifies how ground surface temperatures affect groundwater discharge from hillslopes with water tracks in the upland Arctic by employing a three‐dimensional, physically based subsurface flow model with variable saturation and freeze and thaw capabilities that is calibrated to field measurements from the Upper Kuparuk River watershed on the North Slope of Alaska, USA. Model analysis indicates that higher ground surface temperatures along water track hillslopes promote increases in groundwater discharge where water tracks act as conduits for large‐recharge events and continue to discharge groundwater into the autumn after the adjacent hillslope has frozen. Simulating the conditions that distinguish water tracks from their hillslope watersheds changes subsurface water storage and ground thermal responses but does not alter the total magnitude of groundwater discharge outside of parameter uncertainty. These findings suggest that water tracks play a complex and critical role in hydrologic cycles of the upland Arctic.

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“…summer water deficits clearly became stronger in the twentieth century in Great Britain as a result of increasing temperatures mainly, although winter rainfall -and potentially winter flows -influences groundwater recharge and reservoir supply particularly in England and Wales (Marsh et al, 2007;Fowler and Kilsby, 2002).…”

Section: The Future Flows Hydrology Datasetmentioning

confidence: 99%

Future hot-spots for hydro-hazards in Great Britain: a probabilistic assessment

Collet

Harrigan

Prudhomme

et al. 2018

Hydrol. Earth Syst. Sci.

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Abstract. In an increasing hydro-climatic risk context as a result of climate change, this work aims to identify future hydro-hazard hot-spots as a result of climate change across Great Britain. First, flood and drought hazards were defined and selected in a consistent and parallel approach with a threshold method. Then, a nation-wide systematic and robust statistical framework was developed to quantify changes in frequency, magnitude, and duration, and assess time of year for both droughts and floods, and the uncertainty associated with climate model projections. This approach was applied to a spatially coherent statistical database of daily river flows (Future Flows Hydrology) across Great Britain to assess changes between the baseline (1961–1990) and the 2080s (2069–2098). The results showed that hydro-hazard hot-spots are likely to develop along the western coast of England and Wales and across north-eastern Scotland, mainly during the winter (floods) and autumn (droughts) seasons, with a higher increase in drought hazard in terms of magnitude and duration. These results suggest a need for adapting water management policies in light of climate change impact, not only on the magnitude, but also on the timing of hydro-hazard events, and future policy should account for both extremes together, alongside their potential future evolution.

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Use of Flood Seasonality in Pooling‐Group Formation and Quantile Estimation: An Application in Great Britain

Cited by 13 publications

References 40 publications

Pooled frequency analysis for intensity–duration–frequency curve estimation

Pooled frequency analysis for intensity–duration–frequency curve estimation

Water Tracks Enhance Water Flow Above Permafrost in Upland Arctic Alaska Hillslopes

Future hot-spots for hydro-hazards in Great Britain: a probabilistic assessment

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