Projected changes in droughts and extreme droughts in Great Britain strongly influenced by the choice of drought index

Reyniers, Nele; Osborn, Timothy J.; Addor, Nans; Darch, Geoff

doi:10.5194/hess-2022-94

Cited by 7 publications

(7 citation statements)

References 64 publications

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“…For instance, SPI is widely applied and can detect drought conditions at different timescales, ranging from monthly to multi‐annual (Mckee et al., 1993). However, SPI is based on precipitation alone and fails to consider the role of temperature on drought events and frequencies (Reyniers et al., 2022) and may not be suitable for drought projections and changes under climate change (Vicente‐Serrano, et al., 2020a). Similarly, for hydrological drought, Standardized Streamflow Index (SSI) only considers streamflow, whereas water managers may be interested in other hydrological components such as groundwater that may be critical in understanding the development and duration of drought events (Wossenyeleh et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

Propagation and Characteristics of Hydrometeorological Drought Under Changing Climate in Irish Catchments

2023

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Hydrometeorological droughts are complex hazards expressed through the relative deviation in water availability relative to long-term average conditions. They are typically slow onset, propagating through the water cycle to affect different social, economic, and environmental sectors at different temporal and spatial scales (Ayantobo et al., 2017;Gaitán et al., 2020;Quevauviller & Gemmer, 2015). Furthermore, flash droughts with rapid onset propagate through different spatial-temporal scales, from atmospheric to surface conditions (Shah et al., 2022). Although drought is predominantly caused by a lack of precipitation, soil moisture and streamflow, other factors, like prolonged abstraction and rising atmospheric evaporative demand (AED), can affect drought incidence and propagation. Moreover, the development and propagation of drought is governed by hydrological processes at different spatial scales including precipitation, evapotranspiration, overland flow, soil moisture, groundwater storage and discharge (Ganguli et al., 2022;Sutanto & Van Lanen, 2022). Detailed investigation is thus required to evaluate associated linkages among various types of hydrometeorological drought to understand the likely impacts of climate change on drought characteristics (magnitude, frequency, duration and propagation) at the

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Section: Introductionmentioning

confidence: 99%

Propagation and Characteristics of Hydrometeorological Drought Under Changing Climate in Irish Catchments

2023

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“…The UK has suffered clusters of drought in the form of long and short drought series [79,80]. The following conclusions were drawn with the recent study carried out for the UK indicating projected changes in droughts using SPEI and SPI: increase in drought risk with increasing global mean surface temperature, drought frequency seasonality, duration greatly varies spatially, increase in English regions and Wales, decreases in North and West Scotland, and a large difference between SPI and SPEI was observed [81]. SPEI-6 was the best predictor of drought impacts on agriculture in UK regions compared to the reported drought impacts, however, the findings indicate that the relationship varies spatially between the large heterogeneous regions and needs smaller spatial units [82].…”

Section: Introductionmentioning

confidence: 75%

Assessment of Artificial Neural Network through Drought Indices

Doshi

Mohanasundaram

Akib

2022

Eng

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Prediction of potential evapotranspiration (PET) using an artificial neural network (ANN) with a different network architecture is not uncommon. Most researchers select the optimal network using statistical indicators. However, there is still a gap to be filled in future applications in various drought indices and of assessment of location, duration, average, maximum and minimum. The objective was to compare the performance of PET computed using ANN to the Penman–Monteith technique and compare drought indices standardized precipitation index (SPI) and standardized precipitation evapotranspiration index (SPEI), using two different computed PET for the durations of 1, 3, 6, 9, and 12–months. Statistical performance of predicted PET shows an RMSE of 9.34 mm/month, RSR of 0.28, R2 of 1.00, NSE of 0.92, and PBIAS of −0.04. Predicted PET based on ANN is lower than that the Penman–Monteith approach for maximum values and higher for minimum values. SPEI–Penman–Monteith and SPI have a monthly correlation of greater than 0.95 and similar severity categories, but SPEI is lower than SPI. The average monthly index values for SPEI prediction show that SPEI–ANN captures drought conditions with higher values than SPEI–Penman–Monteith. PET–based ANN, performs robustly in prediction, fails by a degree of severity classification to capture drought conditions when utilized.

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“…Therefore, there is a growing advocacy for the adoption of the SPEI over SPI, as the former includes the evapotranspiration component influenced by rising temperatures (Reyniers et al, 2022;Tomasella et al, 2022;Vicente-Serrano et al, 2022).…”

Section: Propagation From Meteorological Drought To Hydrological Droughtmentioning

confidence: 99%

Propagation from Meteorological Drought to Hydrological Drought Using SPI and SPEI Combined with the Adapted Threshold Level Method

Medeiros,

Silva

2024

Preprint

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Abstract. The hydrological response within a region is often nonlinear, influenced by various factors such as physiographic features, anthropogenic activities, and climate change. Considering the inherent complexity, our study focuses on investigating the propagation from meteorological drought to hydrological drought in the Banabuiú, Castanhão, and Orós reservoirs, located in the State of Ceará, Brazil. To achieve this, we used the Standardized Precipitation Index (SPI) to identify meteorological drought events, which uses precipitation data, alongside the Standardized Precipitation Evapotranspiration Index (SPEI), incorporating potential evapotranspiration in its calculations. For assessing hydrological drought, we used the Adapted Threshold Level Method (ATLM), which calculates the water balance between the supply (represented available reservoir volume) and the demand (including withdrawals for various uses and evaporation losses from the watershed). For all three reservoirs, drought events were characterized by their frequency, duration, severity, magnitude, and drought recovery time across three aggregated time scales of 12, 24, and 36 months. To determine the propagation time from meteorological to hydrological drought, we calculated three indicators, corresponding to time differences between the onsets, peaks, and conclusions of the propagated drought events. Results indicated no significant differences in meteorological drought characteristics between SPI and SPEI methods. However, the SPEI showed higher values for meteorological drought in the Orós watershed. Analysis of drought propagation, employing different methods, revealed no defined pattern for the onset, peak, and end intervals across all tested combinations. Hence, we recommended utilizing all three indicators to enable a more comprehensive analysis of drought events propagated within the watersheds.

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Projected changes in droughts and extreme droughts in Great Britain strongly influenced by the choice of drought index

Cited by 7 publications

References 64 publications

Propagation and Characteristics of Hydrometeorological Drought Under Changing Climate in Irish Catchments

Propagation and Characteristics of Hydrometeorological Drought Under Changing Climate in Irish Catchments

Assessment of Artificial Neural Network through Drought Indices

Propagation from Meteorological Drought to Hydrological Drought Using SPI and SPEI Combined with the Adapted Threshold Level Method

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