Circulation analogues and uncertainty in the time-evolution of extreme event probabilities: evidence from the 1947 Central European heatwave

Harrington, Luke J.; Otto, Friederike E. L.; Cowan, Tim; Hegerl, Gabriele C.

doi:10.1007/s00382-019-04820-2

Cited by 15 publications

(17 citation statements)

References 57 publications

(85 reference statements)

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“…The significance of the modulation patterns is tested at each grid-point and for each phase of the modes through bootstrap resampling (Wang et al 2008;Mazdiyasni and AghaKouchak 2015;Nissan et al 2017;Harrington et al 2019). Let N be the number of days where a given mode is in phase × (or one mode in phase × and another in phase y for the superposition case).…”

Section: Modulation Of Heatwaves By Tropical Modes and Associated Evomentioning

confidence: 99%

Atmospheric tropical modes are important drivers of Sahelian springtime heatwaves

et al. 2020

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Heatwaves pose a serious threat to human health worldwide but remain poorly documented over Africa. This study uses mainly the ERA5 dataset to investigate their large-scale drivers over the Sahel region during boreal spring, with a focus on the role of tropical modes of variability including the Madden–Julian Oscillation (MJO) and the equatorial Rossby and Kelvin waves. Heatwaves were defined from daily minimum and maximum temperatures using a methodology that retains only intraseasonal scale events of large spatial extent. The results show that tropical modes have a large influence on the occurrence of Sahelian heatwaves, and, to a lesser extent, on their intensity. Depending on their convective phase, they can either increase or inhibit heatwave occurrence, with the MJO being the most important of the investigated drivers. A certain sensitivity to the geographic location and the diurnal cycle is observed, with nighttime heatwaves more impacted by the modes over the eastern Sahel and daytime heatwaves more affected over the western Sahel. The examination of the physical mechanisms shows that the modulation is made possible through the perturbation of regional circulation. Tropical modes thus exert a control on moisture and the subsequent longwave radiation, as well as on the advection of hot air. A detailed case study of a major event, which took place in April 2003, further supports these findings. Given the potential predictability offered by tropical modes at the intraseasonal scale, this study has key implications for heatwave risk management in the Sahel.

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Section: Modulation Of Heatwaves By Tropical Modes and Associated Evomentioning

confidence: 99%

Atmospheric tropical modes are important drivers of Sahelian springtime heatwaves

et al. 2020

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“…However, since the sc_PDSI_pm dataset is computed by making use of temperature and precipitation data, both dynamical and thermodynamic changes in the large-scale atmospheric configuration (e.g. Harrington et al, 2019;Pfahl et al, 2017) can affect the spatiotemporal patterns of sc_PDSI_pm wet and dry extremes. This implies for example that storm tracks, blocking, localised convection, along with the increased water-holding capacity of the atmosphere due to warmer temperatures (Trenberth, 2011) may have played a role in shaping the observed predominance of wet and dry extremes.…”

Section: Discussionmentioning

confidence: 99%

Concurrent Hydroclimatic Hazards from Catchment to Global Scales

Luca¹

2020

Preprint

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Interactions between multiple hazards can cause socio-economic damages that exceed those expected by the individual hazard components. Over the past decade, the multi-hazards paradigm has emerged to the extent that the Sendai Framework for Disaster Risk Reduction 2015-2030 advocated a multi-hazard approach. This thesis examines three types of concurrent hydroclimatic hazards that can occur at catchment to global scales. The first multi-hazard is the link between multi-basin flooding (MBF) and extra-tropical cyclones (ETCs) over Great Britain during the period 1975-2014. Results show that during the most geographically widespread MBF episode, up to 108 river catchments (or ~46% of the study area) recorded a peak flow annual maximum within a 16-day window. Most extreme MBF episodes were linked to cyclonic Lamb Weather Types (LWTs), atmospheric rivers and very severe gales. These episodes were associated with significant socio-economic impacts due to widespread flooding. The second hazard was observed (1971-2000) and projected (2011-2100) LWTs, whose seasonal frequency and persistence are associated with multi-hazards over the British Isles. Daily sea-level-pressure data from two reanalyses products, one subjective weather pattern catalogue and an ensemble of 10 Atmosphere-Ocean General Circulation Models (AOGCMs) were used to compute LWTs. Results showed that the AOGCMs are overall able to reproduce historical weather pattern persistence, which, along with annual frequency, is projected to significantly increase anticyclonic and decrease cyclonic LWTs, in summer and autumn respectively. This implies a higher risk of drought, heatwaves and air pollution events in summer but reduced likelihood of flooding and severe gales in autumn by the end of the 21st century. By 2100, the AOGCMs suggest an increased risk of concurrent flood-wind hazards during winter. In summer, the strength of the nocturnal Urban Heat Island (UHI) of London is expected to intensify by the end of the century, contributing to higher chances of combined heatwave-air pollution events. The third type of multi-hazard investigated was the spatio-temporal concurrence of global wet and dry hydrological extremes, during the 1950-2014 period. The analysis was conducted using the monthly self-calibrated Palmer Drought Severity Index based on the Penman-Monteith model (sc_PDSI_pm). Results showed that the land area impacted by extreme dry and wet-dry events significantly increased over the observational period. The most geographically widespread wet-dry event covered a total area of 21 million km2 (or 14% of the global land area) with documented flood and drought impacts over diverse regions. Two new metrics were developed to provide more insight into the combined wet and dry hazards: the wet-dry (WD) ratio and the extreme transitions (ET) time interval. The former quantifies the predominance of wet or dry extremes over a given area, whereas the ET measures the average separation time between the opposite extremes (i.e. between wet to dry or dry to wet transitions). The WD-ratio reveals a predominance of wet over dry extremes in the USA, northern and southern south America, northern Europe, north Africa, western China and most of Australia. The ET median for wet to dry is ~27 months, and 21 months for dry to wet. Global correlations between wet-dry hydrological extremes and El Niño Southern Oscillation (ENSO), Pacific Decadal Oscillation (PDO) and American Multidecadal Oscillation (AMO) were also investigated. ENSO and PDO showed similar correlation patterns, with the former significantly impacting a larger area. On the other hand, the AMO showed an almost inverse spatial correlation pattern, with an overall larger area impacted. The findings presented in this thesis could be informative for emergency responders and relief agencies, disaster risk reduction practitioners, and (re)insurance companies. For instance, multi-basin flooding co-occurring with ETCs could overwhelm emergency response that depends on support from neighbouring regions that are similarly affected. Economic damages could exceed those insured by households and businesses. Projected rises in nocturnal UHI intensity in London could exacerbate heat-stress and, when combined with episodes of poor air quality, increase the likelihood of health problems amongst vulnerable groups. Furthermore, concurrent wet and dry hydrological extremes could be significant for organizations with global assets or sensitive supply chains, and the hydropower, agricultural and transport sectors. Global maps generated of major wet-dry events and the WD-ratio could also be integrated into a seasonal forecasting product, to help stakeholders in hedging the risk. Key opportunities for further research on multi-hazards are future hydroclimatic projections in the light of anthropogenic climate change and the application of new statistical techniques that could help in discerning the driving physical processes.

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“…Further, the definition of heatwaves as adopted here and also followed elsewhere (Mazdiyasni et al, 2019;Ouarda & Charron, 2018;Saeed et al, 2021), allows modeling of annual occurrence probability of consecutive warm days and resulting dry spells associated with this event. While subjective, the choice of the 2 to 10-day time window for analyzing heat stress, is typically followed in the literature (Khaliq et al 2005;Mazdiyasni et al 2019;Harrington et al 2019). Recently, Harrington et al (2019) have chosen a continuous 12-day period in the middle of the summer to define the '1947 heatwave' over central Europe during which temperature was found to be persistently high with a similar circulation state throughout.…”

Section: Heat Stress Characterization and It's Time Evolutionmentioning

confidence: 99%

“…While subjective, the choice of the 2 to 10-day time window for analyzing heat stress, is typically followed in the literature (Khaliq et al 2005;Mazdiyasni et al 2019;Harrington et al 2019). Recently, Harrington et al (2019) have chosen a continuous 12-day period in the middle of the summer to define the '1947 heatwave' over central Europe during which temperature was found to be persistently high with a similar circulation state throughout. Further, in south Asia, atmospheric patterns during heatwaves are often linked to large-scale blocking in mid-latitudes that may persist several consecutive days to weeks (Li et al 2019;Min et al 2020), which justifies our choice of a 10day time window to define the evolution of heatwaves.…”

Section: Heat Stress Characterization and It's Time Evolutionmentioning

confidence: 99%

Amplified Risk of Compound Heat Stress-Dry Spells in Urban India

Ganguli

2021

Preprint

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Compound warm-dry spells over land, which is expected to occur more frequently and expected to cover a much larger spatial extent in a warming climate, result from the simultaneous or successive occurrence of extreme heatwaves, low precipitation, and synoptic conditions, e.g., low surface wind speeds. While changing patterns of weather and climate extremes cannot be ameliorated, effective mitigation requires an understanding of the multivariate nature of interacting drivers that influence the occurrence frequency and predictability of these extremes. However, risk assessments are often focused on univariate statistics, incorporating either extreme temperature or low precipitation; or at the most bivariate statistics considering concurrence of temperature versus precipitation, without accounting for synoptic conditions influencing their joint dependency. Based on station-based daily meteorological records from 23 urban and peri-urban locations of India, covering the 1970-2018 period, this study identifies four distinct regions that show temporal clustering of the timing of heatwaves. Further, combining joint probability distributions of interacting drivers, this analysis explored compound warm-dry potentials that result from the co-occurrence of warmer temperature, scarcer precipitation, and synoptic wind patterns. The results reveal a 50-year severe heat stress tends to be more frequent and is expected to become 5 to 17-year events at each location. Notably, considering dependence among drivers, a median 6-fold amplification (ranging from 3 to 10-fold) in compound warm-dry spell frequency is apparent relative to the expected annual number of a local 50-year severe heatwave episode, indicating warming-induced desiccation is already underway over most of the urbanized areas of the country.

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Circulation analogues and uncertainty in the time-evolution of extreme event probabilities: evidence from the 1947 Central European heatwave

Cited by 15 publications

References 57 publications

Atmospheric tropical modes are important drivers of Sahelian springtime heatwaves

Atmospheric tropical modes are important drivers of Sahelian springtime heatwaves

Concurrent Hydroclimatic Hazards from Catchment to Global Scales

Amplified Risk of Compound Heat Stress-Dry Spells in Urban India

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