Skip to content
Natural Environment Research Council
Grants on the Web - Return to homepage Logo

Details of Award

NERC Reference : NE/N014057/1

Back to previous page

The stratospheric impact on extreme weather events

Fellowship Award

Fellow:
Professor DM Mitchell, University of Bristol, Geographical Sciences
Grant held at:
University of Bristol, Geographical Sciences
Science Area:
Atmospheric
Overall Classification:
Panel B
Science Classification details
ENRIs:
Environmental Risks and Hazards
Global Change
Science Topics:
Stratospheric Processes
Greenhouse gases
Polar vortices
Stratospheric circulation
Climate & Climate Change
Regional & Extreme Weather
Abstract:
The winter of 2013/2014 has seen some of the coldest temperatures in the USA, and some of the heaviest rainfall in the Southern UK ever reported. Both are examples of extreme weather events, the impact of which is enormous on national infrastructure and economy. Current research suggests that the frequency of extreme events is increasing, with strong indications this may be due to humans pumping greenhouse gases into the atmosphere. While the weather on Earth occurs within the troposphere (the layer of the atmosphere between ~0-10km), the stratosphere (~10-50km) is known to play an important role in driving such weather events, especially during winter. The purpose of this project is to understand exactly how the stratosphere influences extreme weather events, and how this follows through to impacts on society, such as infrastructure damage, which can run into billions of pounds, and human deaths, which can be in the tens of thousands. As climate scientists, one tool available to us in understanding atmospheric dynamics and extremes, are computer models of our current and future climate. These models are similar to those that produce the weather forecasts seen on TV, but are adapted to be relevant for longer timescales. In this project the 'weather@home' framework will be utilised, which allows for the model simulations to be run on thousands of volunteered home computers, spreading the load and allowing for many more simulations to be run than otherwise possible. As the climate system is inherently chaotic, it is unlikely that the models will reproduce exactly the observed climate. Therefore typically on supercomputers, models are run ~5-10 times over the same time period, with slightly different starting conditions each time, to build up an ensemble of 'possible' climate scenarios. The advantage of the weather@home set up is that the models can be run many more times than this (of the order of 10,000). This is essential when considering extreme weather events, because they are by definition rare, and the events will only be captured in ~5% of the model simulations. Currently, the weather@home set up does not include a stratosphere-resolving model. This is a big issue because without the stratosphere providing a source of variability for extreme events at the surface, attribution statements, predictability, and ultimately estimated societal impacts will be biased. In this project the model will be further developed to include higher vertical resolution, allowing for a well-resolved stratosphere. Initial assessment will be to analyse the stratospheric dynamics that lead to these rare events at the surface. While it has been known that the stratosphere can influence the troposphere for over a decade, the driving conditions behind this are largely unknown. How the stratosphere impacts surface extreme climate is largely unknown, with most previous research focussing on the mean-state. With the shear number of model simulations available to capture internal climate variability, this project is ideally aimed at addressing questions relating to extremes. An advantage of using climate models (in conjunction with observations) is that they allow for experiments that cannot be tested in the real world. Such as what the climate would be like if humans never existed. In this project such experiments will also be performed to assess how the climate can be forced from different sources of variability. Experiments will be set up to look at how stratosphere-troposphere coupling, and subsequently the extreme events are influences by human induced climate change. Given the recent increase in extreme event attribution globally (for instance, the recent National Academy of Sciences review panel on this issue), an increased understanding of the processes driving extreme events will be invaluable for the scientific community.
Period of Award:
1 Dec 2016 - 30 Nov 2022
Value:
£437,283
(FY details)
Authorised funds only
NERC Reference:
NE/N014057/1
Grant Stage:
Completed
Scheme:
Research Fellowship
Grant Status:
Closed
Programme:
IRF

This fellowship award has a total value of £437,283  

top of page


FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDI - StaffDA - Estate CostsDA - Other Directly AllocatedDI - T&S
£20,082£144,803£224,084£29,036£836£18,443

If you need further help, please read the user guide.