8 results on '"MITCHELL, DANIEL M."'
Search Results
2. U.K. Climate Projections: Summer Daytime and Nighttime Urban Heat Island Changes in England's Major Cities.
- Author
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LO, Y. T. EUNICE, MITCHELL, DANIEL M., BOHNENSTENGEL, SYLVIA I., COLLINS, MAT, HAWKINS, ED, HEGERL, GABRIELE C., JOSHI, MANOJ, and STOTT, PETER A.
- Abstract
In the United Kingdom, where 90% of residents are projected to live in urban areas by 2050, projecting changes in urban heat islands (UHIs) is essential to municipal adaptation. Increased summer temperatures are linked to increased mortality. Using the new regional U.K. Climate Projections, UKCP18-regional, we estimate the 1981--2079 trends in summer urban and rural near-surface air temperatures and in UHI intensities during day and at night in the 10 most populous built-up areas in England. Summer temperatures increase by 0.45°0.81°C per decade under RCP8.5, depending on the time of day and location. Nighttime temperatures increase more in urban than rural areas, enhancing the nighttime UHI by 0.01°-0.05°C per decade in all cities. When these upward UHI signals emerge from 2008-18 variability, positive summer nighttime UHI intensities of up to 1.8°C are projected in most cities. However, we can prevent most of these upward nighttime UHI signals from emerging by stabilizing climate to the Paris Agreement target of 2°C above preindustrial levels. In contrast, daytime UHI intensities decrease in nine cities, at rates between -0.004° and -0.05°C per decade, indicating a trend toward a reduced daytime UHI effect. These changes reflect different feedbacks over urban and rural areas and are specific to UKCP18-regional. Future research is important to better understand the drivers of these UHI intensity changes. [ABSTRACT FROM AUTHOR]
- Published
- 2020
- Full Text
- View/download PDF
3. Biogeophysical Impacts of Land‐Use Change on Climate Extremes in Low‐Emission Scenarios: Results From HAPPI‐Land.
- Author
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Hirsch, Annette L., Guillod, Benoit P., Seneviratne, Sonia I., Beyerle, Urs, Boysen, Lena R., Brovkin, Victor, Davin, Edouard L., Doelman, Jonathan C., Kim, Hyungjun, Mitchell, Daniel M., Nitta, Tomoko, Shiogama, Hideo, Sparrow, Sarah, Stehfest, Elke, van Vuuren, Detlef P., and Wilson, Simon
- Subjects
LAND use ,CLIMATE change ,GLOBAL warming - Abstract
Abstract: The impacts of land use have been shown to have considerable influence on regional climate. With the recent international commitment to limit global warming to well below 2°C, emission reductions need to be ambitious and could involve major land‐use change (LUC). Land‐based mitigation efforts to curb emissions growth include increasing terrestrial carbon sequestration through reforestation, or the adoption of bioenergy crops. These activities influence local climate through biogeophysical feedbacks, however, it is uncertain how important they are for a 1.5° climate target. This was the motivation for HAPPI‐Land: the half a degree additional warming, prognosis, and projected impacts—land‐use scenario experiment. Using four Earth system models, we present the first multimodel results from HAPPI‐Land and demonstrate the critical role of land use for understanding the characteristics of regional climate extremes in low‐emission scenarios. In particular, our results show that changes in temperature extremes due to LUC are comparable in magnitude to changes arising from half a degree of global warming. We also demonstrate that LUC contributes to more than 20% of the change in temperature extremes for large land areas concentrated over the Northern Hemisphere. However, we also identify sources of uncertainty that influence the multimodel consensus of our results including how LUC is implemented and the corresponding biogeophysical feedbacks that perturb climate. Therefore, our results highlight the urgent need to resolve the challenges in implementing LUC across models to quantify the impacts and consider how LUC contributes to regional changes in extremes associated with sustainable development pathways. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
4. Australia's Unprecedented Future Temperature Extremes Under Paris Limits to Warming.
- Author
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Lewis, Sophie C., King, Andrew D., and Mitchell, Daniel M.
- Abstract
Record-breaking temperatures can detrimentally impact ecosystems, infrastructure, and human health. Previous studies show that climate change has influenced some observed extremes, which are expected to become more frequent under enhanced future warming. Understanding the magnitude, as a well as frequency, of such future extremes is critical for limiting detrimental impacts. We focus on temperature changes in Australian regions, including over a major coral reef-building area, and assess the potential magnitude of future extreme temperatures under Paris Agreement global warming targets (1.5°C and 2°C). Under these limits to global mean warming, we determine a set of projected high-magnitude unprecedented Australian temperature extremes. These include extremes unexpected based on observational temperatures, including current record-breaking events. For example, while the difference in global-average warming during the hottest Australian summer and the 2°C Paris target is 1.1°C, extremes of 2.4°C above the observed summer record are simulated. This example represents a more than doubling of the magnitude of extremes, compared with global mean change, and such temperatures are unexpected based on the observed record alone. Projected extremes do not necessarily scale linearly with mean global warming, and this effect demonstrates the significant potential benefits of limiting warming to 1.5°C, compared to 2°C or warmer. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
5. weather@home 2: validation of an improved global-regional climate modelling system.
- Author
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Guillod, Benoit P., Jones, Richard G., Bowery, Andy, Haustein, Karsten, Massey, Neil R., Mitchell, Daniel M., Otto, Friederike E. L., Sparrow, Sarah N., Uhe, Peter, Wallom, David C. H., Wilson, Simon, and Allen, Myles R.
- Subjects
ATMOSPHERIC models ,CLIMATE change ,ECOLOGICAL heterogeneity ,METEOROLOGICAL precipitation ,ATMOSPHERIC physics - Abstract
Extreme weather events can have large impacts on society and, in many regions, are expected to change in frequency and intensity with climate change. Owing to the relatively short observational record, climate models are useful tools as they allow for generation of a larger sample of extreme events, to attribute recent events to anthropogenic climate change, and to project changes in such events into the future. The modelling system known as weather@home, consisting of a global climate model (GCM) with a nested regional climate model (RCM) and driven by sea surface temperatures, allows one to generate a very large ensemble with the help of volunteer distributed computing. This is a key tool to understanding many aspects of extreme events. Here, a new version of the weather@home system (weather@home 2) with a higher-resolution RCM over Europe is documented and a broad validation of the climate is performed. The new model includes a more recent land-surface scheme in both GCM and RCM, where subgrid-scale land-surface heterogeneity is newly represented using tiles, and an increase in RCM resolution from 50 to 25 km. The GCM performs similarly to the previous version, with some improvements in the representation of mean climate. The European RCM temperature biases are overall reduced, in particular the warm bias over eastern Europe, but large biases remain. Precipitation is improved over the Alps in summer, with mixed changes in other regions and seasons. The model is shown to represent the main classes of regional extreme events reasonably well and shows a good sensitivity to its drivers. In particular, given the improvements in this version of the weather@home system, it is likely that more reliable statements can be made with regards to impact statements, especially at more localized scales. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
6. weather@home 2: validation of an improved global-regional climate modelling system.
- Author
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Guillod, Benoit P., Bowery, Andy, Haustein, Karsten, Jones, Richard G., Massey, Neil R., Mitchell, Daniel M., Otto, Friederike E. L., Sparrow, Sarah N., Uhe, Peter, Wallom, David C. H., Wilson, Simon, and Allen, Myles R.
- Subjects
CLIMATE change ,ATMOSPHERIC models ,OCEAN temperature ,LAND surface temperature - Abstract
Extreme weather events can have large impacts on society and, in many regions, are expected to change in frequency and intensity with climate change. Owing to the relatively short observational record, climate models are useful tools as they allow for generation of a larger sample of extreme events, to attribute recent events to anthropogenic climate change, and to project changes of such events into the future. The modelling system known as weather@home, consisting of a global climate model (GCM) with a nested regional climate model (RCM) and driven by sea surface temperatures, allows to generate very large ensemble with the help of volunteer distributed computing. This is a key tool to understanding many aspects of extreme events. Here, a new version of weather@home system (weather@home 2) with a higher resolution RCM over Europe is documented and a broad validation of the climate is performed. The new model includes a more recent land-surface scheme in both GCM and RCM, where subgrid scale land surface heterogeneity is newly represented using tiles, and an increase in RCM resolution from 50 km to 25 km. The GCM performs similarly to the previous version, with some improvements in the representation of mean climate. The European RCM biases are overall reduced, in particular the warm and dry bias over eastern Europe, but large biases remain. The model is shown to represent main classes of regional extreme events reasonably well and shows a good sensitivity to its drivers. In particular, given the improvements in this version of the weather@home system, it is likely that more reliable statements can be made with regards to impact statements, especially at more localized scales. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
7. The Effect of Climate Change on the Variability of the Northern Hemisphere Stratospheric Polar Vortex.
- Author
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Mitchell, Daniel M., Osprey, Scott M., Gray, Lesley J., Butchart, Neal, Hardiman, Steven C., Charlton-Perez, Andrew J., and Watson, Peter
- Subjects
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CLIMATE change , *POLAR vortex , *STRATOSPHERIC circulation , *GREENHOUSE gases & the environment , *ZONAL winds , *TROPOSPHERIC circulation - Abstract
With extreme variability of the Arctic polar vortex being a key link for stratosphere-troposphere influences, its evolution into the twenty-first century is important for projections of changing surface climate in response to greenhouse gases. Variability of the stratospheric vortex is examined using a state-of-the-art climate model and a suite of specifically developed vortex diagnostics. The model has a fully coupled ocean and a fully resolved stratosphere. Analysis of the standard stratospheric zonal mean wind diagnostic shows no significant increase over the twenty-first century in the number of major sudden stratospheric warmings (SSWs) from its historical value of 0.7 events per decade, although the monthly distribution of SSWs does vary, with events becoming more evenly dispersed throughout the winter. However, further analyses using geometric-based vortex diagnostics show that the vortex mean state becomes weaker, and the vortex centroid is climatologically more equatorward by up to 2.5°, especially during early winter. The results using these diagnostics not only characterize the vortex structure and evolution but also emphasize the need for vortex-centric diagnostics over zonally averaged measures. Finally, vortex variability is subdivided into wave-1 (displaced) and -2 (split) components, and it is implied that vortex displacement events increase in frequency under climate change, whereas little change is observed in splitting events. [ABSTRACT FROM AUTHOR]
- Published
- 2012
- Full Text
- View/download PDF
8. Correction.
- Author
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MITCHELL, DANIEL M., OSPREY, SCOTT M., GRAY, LESLEY J., BUTCHART, NEAL, HARDIMAN, STEVEN C., CHARLTON-PEREZ, ANDREW J., and WATSON, PETER
- Subjects
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CLIMATE change - Abstract
A correction to the article "The Effect of Climate Changes on the Variability of the Northern Hemisphere Stratospheric Polar Vortex," by Mitchell and colleagues, is presented.
- Published
- 2012
- Full Text
- View/download PDF
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