Seamless climate change projections and seasonal predictions for bushfires in Australia
Andrew J. Dowdy AJournal of Southern Hemisphere Earth Systems Science 70(1) 120-138 https://doi.org/10.1071/ES20001
Submitted: 19 July 2020 Accepted: 7 December 2020 Published: 17 December 2020
Journal Compilation © BoM 2020 Open Access CC BY-NC-ND
Abstract
Spatio-temporal variations in fire weather conditions are presented based on various data sets, with consistent approaches applied to help enable seamless services over different time scales. Recent research on this is shown here, covering climate change projections for future years throughout this century, predictions at multi-week to seasonal lead times and historical climate records based on observations. Climate projections are presented based on extreme metrics with results shown for individual seasons. A seasonal prediction system for fire weather conditions is demonstrated here as a new capability development for Australia. To produce a more seamless set of predictions, the data sets are calibrated based on quantile-quantile matching for consistency with observations-based data sets, including to help provide details around extreme values for the model predictions (demonstrating the quantile matching for extremes method). Factors influencing the predictability of conditions are discussed, including pre-existing fuel moisture, large-scale modes of variability, sudden stratospheric warmings and climate trends. The extreme 2019–2020 summer fire season is discussed, with examples provided on how this suite of calibrated fire weather data sets was used, including long-range predictions several months ahead provided to fire agencies. These fire weather data sets are now available in a consistent form covering historical records back to 1950, long-range predictions out to several months ahead and future climate change projections throughout this century. A seamless service across different time scales is intended to enhance long-range planning capabilities and climate adaptation efforts, leading to enhanced resilience and disaster risk reduction in relation to natural hazards.
Keywords: bushfires, climate change projections, climate extremes, dangerous weather conditions, disaster risk reduction, natural hazards, seasonal predictions, wildfires.
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