Professor Myles Allen CBE FRS

Concerns over calculating injury-related deaths associated with temperature.

Nature medicine 26:12 (2020) 1825-1826

Authors:

Dann Mitchell, Myles Allen, Kristie L Ebi, Antonio Gasparrini, Clare Heaviside, YT Eunice Lo, Ana M Vicedo-Cabrera

Sustainable financing of permanent CO2 disposal through a Carbon Takeback Obligation

(2020)

Authors:

Stuart Jenkins, Eli Mitchell-Larson, Stuart Haszeldine, Myles Allen

An analysis of ways to decarbonize conference travel after COVID-19

Nature Nature Research 583 (2020) 356-360

Authors:

Milan Klower, Deborah Hopkins, Myles Allen, James Higham

A multi-model assessment of the changing risks of extreme rainfall events in Bangladesh under 1.5 and 2.0 degrees’ warmer worlds

Proceedings of the EGU General Assembly 2020 Copernicus GmbH (2020)

Authors:

Ruksana Haque Rimi, Karsten Haustein, Emily Barbour, Sarah Sparrow, Sihan Li, David Wallom, Myles Allen

Multi-thousand member ensemble atmospheric simulations with global 60km resolution using climateprediction.net

Proceedings of the EGU General Assembly 2020 Copernicus GmbH (2020)

Authors:

Peter Watson, Sarah Sparrow, William Ingram, Simon Wilson, Drouard Marie, Giuseppe Zappa, Richard Jones, Daniel Mitchell, Tim Woollings, Myles Allen

Abstract:

Multi-thousand member climate model simulations are highly valuable for showing how extreme weather events will change as the climate changes, using a physically-based approach. However, until now, studies using such an approach have been limited to using models with a resolution much coarser than the most modern systems. We have developed a global atmospheric model with 5/6°x5/9° resolution (~60km in middle latitudes) that can be run in the climateprediction.net distributed computing system to produce such large datasets. This resolution is finer than that of many current global climate models and sufficient for good simulation of extratropical synoptic features such as storms. It will also allow many extratropical extreme weather events to be simulated without requiring regional downscaling. We will show that this model's simulation of extratropical weather is competitive with that in other current models. We will also present results from the first multi-thousand member ensembles produced at this resolution, showing the impact of 1.5°C and 2°C global warming on extreme winter rainfall and extratropical cyclones in Europe.