I am an atmospheric modeller at the Exoplanet Theory Group. I use numerical models, mostly 3D general circulation models (GCMs), to understand the physical and chemical processes on solar system and extrasolar planets. I am leading the adaptation of LFRic, the Met Office's new weather & climate model, to planetary atmospheres. I am a co-lead of NASA NExSS CUISINES, an international collaboration on exoplanet model intercomparisons. I use Python for data analysis and visualisation. I am an advocate for open-source research software.
- π¬οΈ aeolus - a toolkit for the analysis and visualisation of atmospheric model output
- π§ octant - Objective Cyclone Tracking ANalysis Tools
- π§ LFRic for sub-Neptunes and hot Jupiters (in prep.)
- βοΈ Thunderstruck (in prep.)
- π The impact of convection on the climate of a tidally locked planet in global stretched-mesh simulations
- π Simulations of idealised 3D atmospheric flows on terrestrial planets using LFRic-Atmosphere
- π Bistability of atmospheric circulation on TRAPPIST-1e
- π The TRAPPIST-1 Habitable Atmosphere Intercomparison (THAI)
- βοΈ Atmospheric convection plays a key role in the climate of tidally-locked terrestrial exoplanets
Polar mesoscale cyclones in ERA5 and ERA-Interim over the Nordic Seas region (rejected)- β°οΈ Modification of Polar Low Development by Orography and Sea Ice
- π Structure of a shear-line polar low