A large set of potential past, present and future hydro-meteorological time series for the UK

Guillod, Benoît P.; Jones, R. G.; Dadson, Simon; Coxon, Gemma; Bussi, Gianbattista; Freer, J. E.; Kay, Alison L.; Massey, Neil; Sparrow, Sarah; Wallom, David; Allen, Myles; Hall, Jim W.

doi:10.5194/hess-22-611-2018

Cited by 57 publications

(92 citation statements)

References 42 publications

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“…Uncertainty in projections of future climate change arises from multiple sources—in particular, internal climate variability, climate model uncertainty, and emissions uncertainty. Our study has used the future meteorological data of Guillod et al () who used a single global climate model‐regional climate model (with sampling from the CMIP5 uncertainty range in sea surface temperature and sea ice extent) and “worst‐case” RCP (RCP8.5). However, Kirtman et al () demonstrate that the uncertainty due to emissions for the near future is minimal, given the limited divergence in global greenhouse gas emissions associated with each RCP and ocean‐atmosphere system lags.…”

Section: Discussionmentioning

confidence: 99%

“…The hydrometeorological data set used in this study was produced within the MaRIUS project (http://www.mariusdroughtproject.org/; Managing the Risks, Impacts and Uncertainties of droughts and water Scarcity), using the weather@home2 modeling framework (Guillod et al, ; Massey et al, ), in which the HadAM3P atmosphere‐global climate model is dynamically downscaled by the HadRM3P regional climate model. Accounting for uncertainty through application of small perturbations to the temperature field in the initial conditions (Massey et al, ) and sampling from the CMIP5 uncertainty range in sea surface temperature and sea ice extent allowed a large number (100) of spatial‐temporally consistent ensemble members to be generated for the recent past and for the future (Guillod et al, ). The data set by Guillod et al () provides synthetic daily weather time series for the United Kingdom at a 25‐km × 25‐km resolution.…”

Section: Methodsmentioning

confidence: 99%

“…Accounting for uncertainty through application of small perturbations to the temperature field in the initial conditions (Massey et al, ) and sampling from the CMIP5 uncertainty range in sea surface temperature and sea ice extent allowed a large number (100) of spatial‐temporally consistent ensemble members to be generated for the recent past and for the future (Guillod et al, ). The data set by Guillod et al () provides synthetic daily weather time series for the United Kingdom at a 25‐km × 25‐km resolution. The baseline (1977–2004) data set provides 100 simulated climate ensemble members that could have occurred in the past, while the near future (2022–2049) and far future (2072–2099) represent climate time series that might occur in the future under the Representative Concentration Pathway 8.5 (RCP8.5) emissions scenario.…”

Section: Methodsmentioning

confidence: 99%

“…The weather@home2 climate ensemble (Guillod et al, ) has been used to drive the national Grid‐to‐Grid (G2G) hydrological model (Bell et al, ) to provide simulated daily river flows for the baseline, near future, and far future periods (Bell, Kay, et al, ; Bell, Rudd, et al, ). For each period, 100 simulations of daily mean river flow for each of 129 catchments across England and Wales have been used in this study.…”

Section: Methodsmentioning

confidence: 99%

“…Two methodological innovations for a probabilistic risk‐based economic assessment in irrigated agriculture are presented. First, it applies current environmental regulatory triggers to daily catchment‐scale rainfall from dynamically downscaled and bias‐corrected climate projections (Guillod et al, ; Guillod et al, ) and simulated river flow from a national‐scale hydrological model (Bell et al, ), to obtain the current and future timing, frequency, severity, and duration of abstraction restrictions. Second, a probabilistic risk‐based analysis of economic losses in irrigated agriculture from catchment to national scale is performed through applying crop‐specific loss functions to a national spatial data set of irrigated cropping (Rey et al, ) according to the timing, duration, and severity of the restrictions.…”

Section: Introductionmentioning

confidence: 99%

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A Probabilistic Risk Assessment of the National Economic Impacts of Regulatory Drought Management on Irrigated Agriculture

et al. 2019

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Drought frequency and intensity is expected to increase in many regions worldwide, and water shortages could become more extreme, even in humid temperate climates. To protect the environment and secure water supplies, water abstractions for irrigation can be mandatorily reduced by environmental regulators. Such abstraction restrictions can result in economic impacts on irrigated agriculture. This study provides a novel approach for the probabilistic risk assessment of potential future economic losses in irrigated agriculture arising from the interaction of climate change and regulatory drought management, with an application to England and Wales. Hydrometeorological variability is considered within a synthetic data set of daily rainfall and river flows for a baseline period (1977–2004) and for projections for near future (2022–2049) and far future (2072–2099). The probability, magnitude, and timing of abstraction restrictions are derived by applying rainfall and river flow triggers in 129 catchments. The risk of economic losses at the catchment level is then obtained from the occurrences of abstraction restrictions combined with spatially distributed crop‐specific economic losses. Results show that restrictions will become more severe, more frequent, and longer in the future. The highest economic risks are projected where drought‐sensitive crops with a high financial value are concentrated in catchments with increasingly uncertain water supply. This research highlights the significant economic losses associated with mandatory drought restrictions experienced by the agricultural sector and supports the need for environmental regulators and irrigators to collaboratively manage scarce water resources to balance environmental and economic considerations.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Probabilistic Risk Assessment of the National Economic Impacts of Regulatory Drought Management on Irrigated Agriculture

et al. 2019

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Risk, Robustness and Water Resources Planning Under Uncertainty

et al. 2018

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Risk‐based water resources planning is based on the premise that water managers should invest up to the point where the marginal benefit of risk reduction equals the marginal cost of achieving that benefit. However, this cost‐benefit approach may not guarantee robustness under uncertain future conditions, for instance under climatic changes. In this paper, we expand risk‐based decision analysis to explore possible ways of enhancing robustness in engineered water resources systems under different risk attitudes. Risk is measured as the expected annual cost of water use restrictions, while robustness is interpreted in the decision‐theoretic sense as the ability of a water resource system to maintain performance—expressed as a tolerable risk of water use restrictions—under a wide range of possible future conditions. Linking risk attitudes with robustness allows stakeholders to explicitly trade‐off incremental increases in robustness with investment costs for a given level of risk. We illustrate the framework through a case study of London's water supply system using state‐of‐the ‐art regional climate simulations to inform the estimation of risk and robustness.

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The MaRIUS‐G2G datasets: Grid‐to‐Grid model estimates of flow and soil moisture for Great Britain using observed and climate model driving data

Bell

Kay

Rudd

et al. 2018

Geoscience Data Journal

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The MaRIUS‐G2G datasets were produced for the MaRIUS (Managing the Risks, Impacts and Uncertainties of drought and water Scarcity) project, using the Grid‐to‐Grid (G2G) national‐scale hydrological model for Great Britain. There are six separate datasets, with each of three combinations of meteorological driving data (two observation‐based and one from climate model ensembles) used to produce two types of outputs (daily time‐series of natural river flow for 260 sites, and monthly 1 × 1 km grids of natural flow and soil moisture in the unsaturated zone). The driving data required by G2G are rainfall and potential evaporation (PE). Two of the datasets from observation‐based driving data use rainfall from CEH‐GEAR (CEH‐Gridded Estimates of Areal Rainfall) with PE from MORECS (Met Office Rainfall and Evaporation Calculation System), and cover the period 1960–2015, while the other two use CEH‐GEAR rainfall with PE derived from 5 km temperature data using the Oudin method, and cover 1891–2015. The two datasets based on driving data (rainfall and PE) from the climate model ensembles cover three periods: Historical Baseline (1900–2006), Near‐Future (2020–2049), and Far‐Future (2070–2099). Data for a 30‐year Baseline period (1975–2004), against which the Near‐Future and Far‐Future periods should be compared, are also available directly. There are 100 members in each ensemble, and the future periods use the RCP8.5 emissions scenario. This paper provides details of the G2G model and the different sets of meteorological driving data, as well as the availability and formatting of the output datasets. It also describes some recent and potential applications of the datasets, which have already been used to support historical and future analyses of low flow and drought characteristics across Britain, and provides some guidance on how the climate model‐driven datasets should (and should not) be used. Open Practices This article has earned an Open Data badge for making publicly available the digitally‐shareable data necessary to reproduce the reported results. The data is available at DOI 10.5285/5f3c1a02-d5c4-4faa-9353-e8b68ce2ace2. Learn more about the Open Practices badges from the Center for Open Science: https://osf.io/tvyxz/wiki.

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A large set of potential past, present and future hydro-meteorological time series for the UK

Cited by 57 publications

References 42 publications

A Probabilistic Risk Assessment of the National Economic Impacts of Regulatory Drought Management on Irrigated Agriculture

A Probabilistic Risk Assessment of the National Economic Impacts of Regulatory Drought Management on Irrigated Agriculture

Risk, Robustness and Water Resources Planning Under Uncertainty

The MaRIUS‐G2G datasets: Grid‐to‐Grid model estimates of flow and soil moisture for Great Britain using observed and climate model driving data

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