Your search keyword '"Kew, Sarah F."' showing total 12 results

1. An attribution study of very intense rainfall events in Eastern Northeast Brazil

Author

Vasconcelos Junior, Francisco das Chagas, Zachariah, Mariam, Silva, Thiago Luiz do Vale, Santos, Edvânia Pereira dos, Coelho, Caio.A.S., Alves, Lincoln M., Martins, Eduardo Sávio Passos Rodrigues, Köberle, Alexandre C., Singh, Roop, Vahlberg, Maja, Marchezini, Victor, Heinrich, Dorothy, Thalheimer, Lisa, Raju, Emmanuel, Koren, Gerbrand, Philip, Sjoukje Y., Kew, Sarah F., Bonnet, Rémy, Li, Sihan, Yang, Wenchang, Sun, Jingru, Vecchi, Gabriel, and Otto, Friederike.E.L.

Published

2024

2. Rapid attribution analysis of the extraordinary heat wave on the Pacific coast of the US and Canada in June 2021

Author

Philip, Sjoukje Y, Kew, Sarah F, van Oldenborgh, Geert Jan, Anslow, Faron S, Seneviratne, Sonia I, Vautard, Robert, Coumou, Dim, Ebi, Kristie L, Arrighi, Julie, Singh, Roop, van Aalst, Maarten, Marghidan, Carolina Pereira, Wehner, Michael, Yang, Wenchang, Li, Sihan, Schumacher, Dominik L, Hauser, Mathias, Bonnet, Rémy, Luu, Linh N, Lehner, Flavio, Gillett, Nathan, Tradowsky, Jordis S, Vecchi, Gabriel A, Rodell, Chris, Stull, Roland B, Howard, Rosie, and Otto, Friederike EL

Subjects

Earth Sciences, Atmospheric Sciences, Climate-Related Exposures and Conditions, Climate Change, Climate Action, Oceanography, Physical Geography and Environmental Geoscience, Climate change science, Geoinformatics

Abstract

Towards the end of June 2021, temperature records were broken by several degrees Celsius in several cities in the Pacific Northwest areas of the US and Canada, leading to spikes in sudden deaths and sharp increases in emergency calls and hospital visits for heat-related illnesses. Here we present a multi-model, multi-method attribution analysis to investigate the extent to which human-induced climate change has influenced the probability and intensity of extreme heat waves in this region. Based on observations, modelling and a classical statistical approach, the occurrence of a heat wave defined as the maximum daily temperature (TXx) observed in the area 45-52N, 119-123W, was found to be virtually impossible without human-caused climate change. The observed temperatures were so extreme that they lay far outside the range of historical temperature observations. This makes it hard to state with confidence how rare the event was. Using a statistical analysis that assumes that the heat wave is part of the same distribution as previous heat waves in this region led to a first-order estimation of the event frequency of the order of once in 1000 years under current climate conditions. Using this assumption and combining the results from the analysis of climate models and weather observations, we found that such a heat wave event would be at least 150 times less common without human-induced climate change. Also, this heat wave was about 2 C hotter than a 1-in-1000-year heat wave would have been in 1850-1900, when global mean temperatures were 1.2 C cooler than today. Looking into the future, in a world with 2 C of global warming (0.8 C warmer than today), a 1000-year event would be another degree hotter. Our results provide a strong warning: our rapidly warming climate is bringing us into uncharted territory with significant consequences for health, well-being and livelihoods. Adaptation and mitigation are urgently needed to prepare societies for a very different future.

Published

2022

3. Attribution of the heavy rainfall events leading to severe flooding in Western Europe during July 2021

Author

Tradowsky, Jordis S., Philip, Sjoukje Y., Kreienkamp, Frank, Kew, Sarah F., Lorenz, Philip, Arrighi, Julie, Bettmann, Thomas, Caluwaerts, Steven, Chan, Steven C., De Cruz, Lesley, de Vries, Hylke, Demuth, Norbert, Ferrone, Andrew, Fischer, Erich M., Fowler, Hayley J., Goergen, Klaus, Heinrich, Dorothy, Henrichs, Yvonne, Kaspar, Frank, Lenderink, Geert, Nilson, Enno, Otto, Friederike E. L., Ragone, Francesco, Seneviratne, Sonia I., Singh, Roop K., Skålevåg, Amalie, Termonia, Piet, Thalheimer, Lisa, van Aalst, Maarten, Van den Bergh, Joris, Van de Vyver, Hans, Vannitsem, Stéphane, van Oldenborgh, Geert Jan, Van Schaeybroeck, Bert, Vautard, Robert, Vonk, Demi, and Wanders, Niko

Published

2023

4. Frontiers in attributing climate extremes and associated impacts.

Author

Perkins-Kirkpatrick, Sarah E., Alexander, Lisa V., King, Andrew D., Kew, Sarah F., Philip, Sjoukje Y., Barnes, Clair, Maraun, Douglas, Stuart-Smith, Rupert F., Jézéquel, Aglaé, Bevacqua, Emanuele, Burgess, Samantha, Fischer, Erich, Hegerl, Gabriele C., Kimutai, Joyce, Koren, Gerbrand, Lawal, Kamoru Abiodun, Min, Seung-Ki, New, Mark, Odoulami, Romaric C., and Patricola, Christina M.

Subjects

CLIMATE change, CAPACITY building, ATMOSPHERIC models, ENVIRONMENTAL sciences, CLIMATE extremes

Abstract

The field of extreme event attribution (EEA) has rapidly developed over the last two decades. Various methods have been developed and implemented, physical modelling capabilities have generally improved, the field of impact attribution has emerged, and assessments serve as a popular communication tool for conveying how climate change is influencing weather and climate events in the lived experience. However, a number of non-trivial challenges still remain that must be addressed by the community to secure further advancement of the field whilst ensuring scientific rigour and the appropriate use of attribution findings by stakeholders and associated applications. As part of a concept series commissioned by the World Climate Research Programme, this article discusses contemporary developments and challenges over six key domains relevant to EEA, and provides recommendations of where focus in the EEA field should be concentrated over the coming decade. These six domains are: (1) observations in the context of EEA; (2) extreme event definitions; (3) statistical methods; (4) physical modelling methods; (5) impact attribution; and (6) communication. Broadly, recommendations call for increased EEA assessments and capacity building, particularly for more vulnerable regions; contemporary guidelines for assessing the suitability of physical climate models; establishing best-practice methodologies for EEA on compound and record-shattering extremes; co-ordinated interdisciplinary engagement to develop scaffolding for impact attribution assessments and their suitability for use in broader applications; and increased and ongoing investment in EEA communication. To address these recommendations requires significant developments in multiple fields that either underpin (e.g., observations and monitoring; climate modelling) or are closely related to (e.g., compound and record-shattering events; climate impacts) EEA, as well as working consistently with experts outside of attribution and climate science more generally. However, if approached with investment, dedication, and coordination, tackling these challenges over the next decade will ensure robust EEA analysis, with tangible benefits to the broader global community. [ABSTRACT FROM AUTHOR]

Published

2024

5. Challenges in the attribution of river flood events.

Author

Scussolini, Paolo, Luu, Linh Nhat, Philip, Sjoukje, Berghuijs, Wouter R., Eilander, Dirk, Aerts, Jeroen C. J. H., Kew, Sarah F., van Oldenborgh, Geert Jan, Toonen, Willem H. J., Volkholz, Jan, and Coumou, Dim

Subjects

FLOODS, FLOOD risk, DAM design & construction, HYDROLOGIC models, GLOBAL warming, CLIMATE change

Abstract

Advances in the field of extreme event attribution allow to estimate how anthropogenic global warming affects the odds of individual climate disasters, such as river floods. Extreme event attribution typically uses precipitation as proxy for flooding. However, hydrological processes and antecedent conditions make the relation between precipitation and floods highly nonlinear. In addition, hydrology acknowledges that changes in floods can be strongly driven by changes in land‐cover and by other human interventions in the hydrological system, such as irrigation and construction of dams. These drivers can either amplify, dampen or outweigh the effect of climate change on local flood occurrence. Neglecting these processes and drivers can lead to incorrect flood attribution. Including flooding explicitly, that is, using data and models of hydrology and hydrodynamics that can represent the relevant hydrological processes, will lead to more robust event attribution, and will account for the role of other drivers beyond climate change. Existing attempts are incomplete. We argue that the existing probabilistic framework for extreme event attribution can be extended to explicitly include floods for near‐natural cases, where flood occurrence was unlikely to be influenced by land‐cover change and human hydrological interventions. However, for the many cases where this assumption is not valid, a multi‐driver framework for conditional event attribution needs to be established. Explicit flood attribution will have to grapple with uncertainties from lack of observations and compounding from the many processes involved. Further, it requires collaboration between climatologists and hydrologists, and promises to better address the needs of flood risk management. This article is categorized under:Paleoclimates and Current Trends > Modern Climate ChangePaleoclimates and Current Trends > Detection and AttributionAssessing Impacts of Climate Change > Observed Impacts of Climate Change [ABSTRACT FROM AUTHOR]

Published

2024

6. Challenges in the attribution of river flood events

Author

Scussolini, Paolo, primary, Luu, Linh Nhat, additional, Philip, Sjoukje, additional, Berghuijs, Wouter R., additional, Eilander, Dirk, additional, Aerts, Jeroen C. J. H., additional, Kew, Sarah F., additional, van Oldenborgh, Geert Jan, additional, Toonen, Willem H. J., additional, Volkholz, Jan, additional, and Coumou, Dim, additional

Published

2023

7. Impact of Surface Roughness Changes on Surface Wind Speed Over Western Europe: A Study With the Regional Climate Model RACMO

Author

Luu, Linh N., primary, van Meijgaard, Erik, additional, Philip, Sjoukje Y., additional, Kew, Sarah F., additional, de Baar, Jouke H. S., additional, and Stepek, Andrew, additional

Published

2023

8. Attribution of the heavy rainfall events leading to severe flooding in Western Europe during July 2021

Author

Landdegradatie en aardobservatie, Landscape functioning, Geocomputation and Hydrology, Tradowsky, Jordis S., Philip, Sjoukje Y., Kreienkamp, Frank, Kew, Sarah F., Lorenz, Philip, Arrighi, Julie, Bettmann, Thomas, Caluwaerts, Steven, Chan, Steven C., De Cruz, Lesley, de Vries, Hylke, Demuth, Norbert, Ferrone, Andrew, Fischer, Erich M., Fowler, Hayley J., Goergen, Klaus, Heinrich, Dorothy, Henrichs, Yvonne, Kaspar, Frank, Lenderink, Geert, Nilson, Enno, Otto, Friederike E.L., Ragone, Francesco, Seneviratne, Sonia I., Singh, Roop K., Skålevåg, Amalie, Termonia, Piet, Thalheimer, Lisa, van Aalst, Maarten, Van den Bergh, Joris, Van de Vyver, Hans, Vannitsem, Stéphane, van Oldenborgh, Geert Jan, Van Schaeybroeck, Bert, Vautard, Robert, Vonk, Demi, Wanders, Niko, Landdegradatie en aardobservatie, Landscape functioning, Geocomputation and Hydrology, Tradowsky, Jordis S., Philip, Sjoukje Y., Kreienkamp, Frank, Kew, Sarah F., Lorenz, Philip, Arrighi, Julie, Bettmann, Thomas, Caluwaerts, Steven, Chan, Steven C., De Cruz, Lesley, de Vries, Hylke, Demuth, Norbert, Ferrone, Andrew, Fischer, Erich M., Fowler, Hayley J., Goergen, Klaus, Heinrich, Dorothy, Henrichs, Yvonne, Kaspar, Frank, Lenderink, Geert, Nilson, Enno, Otto, Friederike E.L., Ragone, Francesco, Seneviratne, Sonia I., Singh, Roop K., Skålevåg, Amalie, Termonia, Piet, Thalheimer, Lisa, van Aalst, Maarten, Van den Bergh, Joris, Van de Vyver, Hans, Vannitsem, Stéphane, van Oldenborgh, Geert Jan, Van Schaeybroeck, Bert, Vautard, Robert, Vonk, Demi, and Wanders, Niko

Published

2023

9. Climate change increased extreme monsoon rainfall, flooding highly vulnerable communities in Pakistan

Author

Otto, Friederike E L, Zachariah, Mariam, Saeed, Fahad, Siddiqi, Ayesha, Kamil, Shahzad, Mushtaq, Haris, T, Arulalan, Achutarao, Krishna, S T, Chaitra, Barnes, Clair, Philip, Sjoukje, Kew, Sarah F, Vautard, Robert, Koren, Gerbrand, Pinto, Izidine, Wolski, Piotr, Vahlberg, Maja, Singh, Roop, Arrighi, Julie, Van Aalst, Maarten, Thalheimer, Lisa, Raju, Emmanuel, Li, Sihan, Yang, Wenchang, Harrington, Luke James, Clarke, Ben, Otto, Friederike E L, Zachariah, Mariam, Saeed, Fahad, Siddiqi, Ayesha, Kamil, Shahzad, Mushtaq, Haris, T, Arulalan, Achutarao, Krishna, S T, Chaitra, Barnes, Clair, Philip, Sjoukje, Kew, Sarah F, Vautard, Robert, Koren, Gerbrand, Pinto, Izidine, Wolski, Piotr, Vahlberg, Maja, Singh, Roop, Arrighi, Julie, Van Aalst, Maarten, Thalheimer, Lisa, Raju, Emmanuel, Li, Sihan, Yang, Wenchang, Harrington, Luke James, and Clarke, Ben

Abstract

As a direct consequence of extreme monsoon rainfall throughout the summer 2022 season Pakistan experienced the worst flooding in its history. We employ a probabilistic event attribution methodology as well as a detailed assessment of the dynamics to understand the role of climate change in this event. Many of the available state-of-the-art climate models struggle to simulate these rainfall characteristics. Those that pass our evaluation test generally show a much smaller change in likelihood and intensity of extreme rainfall than the trend we found in the observations. This discrepancy suggests that long-term variability, or processes that our evaluation may not capture, can play an important role, rendering it infeasible to quantify the overall role of human-induced climate change. However, the majority of models and observations we have analysed show that intense rainfall has become heavier as Pakistan has warmed. Some of these models suggest climate change could have increased the rainfall intensity up to 50%. The devastating impacts were also driven by the proximity of human settlements, infrastructure (homes, buildings, bridges), and agricultural land to flood plains, inadequate infrastructure, limited ex-ante risk reduction capacity, an outdated river management system, underlying vulnerabilities driven by high poverty rates and socioeconomic factors (e.g. gender, age, income, and education), and ongoing political and economic instability. Both current conditions and the potential further increase in extreme peaks in rainfall over Pakistan in light of anthropogenic climate change, highlight the urgent need to reduce vulnerability to extreme weather in Pakistan

Published

2023

10. Impact of Surface Roughness Changes on Surface Wind Speed over Western Europe: A Study with a Regional Climate Model

Author

Luu, Linh N., primary, Meijgaard, Erik Van, additional, Philip, Sjoukje Y., additional, Kew, Sarah F., additional, Baar, Jouke H. S. De, additional, and Stepek, Andrew, additional

Published

2023

11. Attributing and Projecting Heatwaves Is Hard: We Can Do Better

Author

Van Oldenborgh, Geert Jan, primary, Wehner, Michael F., additional, Vautard, Robert, additional, Otto, Friederike E. L., additional, Seneviratne, Sonia I., additional, Stott, Peter A., additional, Hegerl, Gabriele C., additional, Philip, Sjoukje Y., additional, and Kew, Sarah F., additional

Published

2022

12. Rapid attribution analysis of the extraordinary heat wave on the Pacific coast of the US and Canada in June 2021

Author

Philip, Sjoukje Y., Kew, Sarah F., van Oldenborgh, Geert Jan, Anslow, Faron S., Seneviratne, Sonia I., Vautard, Robert, Coumou, Dim, Ebi, Kristie L., Arrighi, Julie, Singh, Roop, van Aalst, Maarten, Pereira Marghidan, Carolina, Wehner, Michael, Yang, Wenchang, Li, Sihan, Schumacher, Dominik L., Hauser, Mathias, Bonnet, Remy, Luu, Linh N., and Lehner, Flavio

Abstract

Towards the end of June 2021, temperature records were broken by several degrees Celsius in several cities in the Pacific Northwest areas of the US and Canada, leading to spikes in sudden deaths and sharp increases in emergency calls and hospital visits for heat-related illnesses. Here we present a multi-model, multi-method attribution analysis to investigate the extent to which human-induced climate change has influenced the probability and intensity of extreme heat waves in this region. Based on observations, modelling and a classical statistical approach, the occurrence of a heat wave defined as the maximum daily temperature (TXx) observed in the area 45-52 degrees N, 119-123 degrees W, was found to be virtually impossible without human-caused climate change. The observed temperatures were so extreme that they lay far outside the range of historical temperature observations. This makes it hard to state with confidence how rare the event was. Using a statistical analysis that assumes that the heat wave is part of the same distribution as previous heat waves in this region led to a first-order estimation of the event frequency of the order of once in 1000 years under current climate conditions. Using this assumption and combining the results from the analysis of climate models and weather observations, we found that such a heat wave event would be at least 150 times less common without human-induced climate change. Also, this heat wave was about 2 degrees C hotter than a 1-in-1000-year heat wave would have been in 1850-1900, when global mean temperatures were 1.2 degrees C cooler than today. Looking into the future, in a world with 2 degrees C of global warming (0.8 degrees C warmer than today), a 1000-year event would be another degree hotter. Our results provide a strong warning: our rapidly warming climate is bringing us into uncharted territory with significant consequences for health, well-being and livelihoods. Adaptation and mitigation are urgently needed to prepare societies for a very different future., Earth System Dynamics, 13 (4), ISSN:2190-4987, ISSN:2190-4979

Published

2022