Model Code and Data for "Sources of Uncertainty in the Global Fire Model SPITFIRE: Development of LPJmL-SPITFIRE1.9 and Directions for Future Improvements"

This repository contains the LPJmL-SPITFIRE1.9 model code, code for the MATLAB implementation of the Rothermel model, and code and data used for the generation of figures in the paper "Sources of Uncertainty in the Global Fire Model SPITFIRE: Development of LPJmL-SPITFIRE1.9 and Directions for Future Improvements."

Abstract

Since its development in 2010, the SPITFIRE global fire model has had a substantial impact on the field of fire modelling using dynamic global vegetation models. It includes process-based representations of fire dynamics, including ignitions, fire spread and fire effects, resulting in a holistic representation of fire on a global scale. Previously, work has been undertaken to understand the strengths and weaknesses of SPITFIRE and similar models by comparing their outputs against remotely sensed data. We seek to augment this work with new validation methods and extend it by completing a thorough review of the theory underlying the SPITFIRE model to better identify and understand sources of modelling uncertainty. We find several points of improvement in the model, the most impactful being an incorrect implementation of the Rothermel fire spread model that results in strong upward biases in fire rate of spread, and a live grass moisture parametrization that results in substantially too low live grass moisture contents. The combination of these issues leads to excessively large and intense fires, particularly on grasslands, that bias SPITFIRE toward high tree mortality. We resolve these issues by correcting the implementation of the Rothermel model and implementing a new live grass moisture parametrization, in addition to several other improvements, including a multi-day fire spread algorithm, and evaluate these changes in the European domain. Our model developments allow SPITFIRE to incorporate more realistic live grass moisture contents, and result in more accurate burnt area on grasslands and reduced tree mortality. This work provides a crucial improvement on the theoretical basis of the SPITFIRE model, and a foundation upon which future model improvements may be built. In addition, this work further supports these model developments by  highlighting areas in the model where high amounts of uncertainty remain, based on new analysis and existing knowledge about the SPITIFRE model, and identifying potential means of mitigating them to a greater extent.