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1. Fire behaviour and smoke modelling: model improvement and measurement needs for next-generation smoke research and forecasting systems

   https://doi.org/10.1071/WF18204  

   Liu, Yongqiang; Kochanski, Adam; Baker, Kirk R.; Mell, William; Linn, Rodman; Paugam, Ronan; Mandel, Jan; Fournier, Aime; Jenkins, Mary Ann; Goodrick, Scott; et al (January 2019, International Journal of Wildland Fire)
2. On the stratospheric chemistry of midlatitude wildfire smoke

   https://doi.org/10.1073/pnas.2117325119  

   Solomon, Susan; Dube, Kimberlee; Stone, Kane; Yu, Pengfei; Kinnison, Doug; Toon, Owen B.; Strahan, Susan E.; Rosenlof, Karen H.; Portmann, Robert; Davis, Sean; et al (March 2022, Proceedings of the National Academy of Sciences)

   Massive Australian wildfires lofted smoke directly into the stratosphere in the austral summer of 2019/20. The smoke led to increases in optical extinction throughout the midlatitudes of the southern hemisphere that rivalled substantial volcanic perturbations. Previous studies have assumed that the smoke became coated with sulfuric acid and water and would deplete the ozone layer through heterogeneous chemistry on those surfaces, as is routinely observed following volcanic enhancements of the stratospheric sulfate layer. Here, observations of extinction and reactive nitrogen species from multiple independent satellites that sampled the smoke region are compared to one another and to model calculations. The data display a strong decrease in reactive nitrogen concentrations with increased aerosol extinction in the stratosphere, which is a known fingerprint for key heterogeneous chemistry on sulfate/H 2 O particles (specifically the hydrolysis of N 2 O 5 to form HNO 3 ). This chemical shift affects not only reactive nitrogen but also chlorine and reactive hydrogen species and is expected to cause midlatitude ozone layer depletion. Comparison of the model ozone to observations suggests that N 2 O 5 hydrolysis contributed to reduced ozone, but additional chemical and/or dynamical processes are also important. These findings suggest that if wildfire smoke injection into the stratosphere increases sufficiently in frequency and magnitude as the world warms due to climate change, ozone recovery under the Montreal Protocol could be impeded, at least sporadically. Modeled austral midlatitude total ozone loss was about 1% in March 2020, which is significant compared to expected ozone recovery of about 1% per decade. 

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3. Smoke pollution's impacts in Amazonia

   https://doi.org/10.1126/science.abd5942  

   de Oliveira, Gabriel; Chen, Jing M.; Stark, Scott C.; Berenguer, Erika; Moutinho, Paulo; Artaxo, Paulo; Anderson, Liana O.; Aragão, Luiz E. (August 2020, Science)

   Sills, Jennifer (Ed.)
4. Multimodal Wildland Fire Smoke Detection

   https://doi.org/10.3390/rs15112790  

   Bhamra, Jaspreet Kaur; Anantha_Ramaprasad, Shreyas; Baldota, Siddhant; Luna, Shane; Zen, Eugene; Ramachandra, Ravi; Kim, Harrison; Schmidt, Chris; Arends, Chris; Block, Jessica; et al (June 2023, Remote Sensing)

   Research has shown that climate change creates warmer temperatures and drier conditions, leading to longer wildfire seasons and increased wildfire risks in the United States. These factors have, in turn, led to increases in the frequency, extent, and severity of wildfires in recent years. Given the danger posed by wildland fires to people, property, wildlife, and the environment, there is an urgent need to provide tools for effective wildfire management. Early detection of wildfires is essential to minimizing potentially catastrophic destruction. To that end, in this paper, we present our work on integrating multiple data sources into SmokeyNet, a deep learning model using spatiotemporal information to detect smoke from wildland fires. We present Multimodal SmokeyNet and SmokeyNet Ensemble for multimodal wildland fire smoke detection using satellite-based fire detections, weather sensor measurements, and optical camera images. An analysis is provided to compare these multimodal approaches to the baseline SmokeyNet in terms of accuracy metrics, as well as time-to-detect, which is important for the early detection of wildfires. Our results show that incorporating weather data in SmokeyNet improves performance numerically in terms of both F1 and time-to-detect over the baseline with a single data source. With a time-to-detect of only a few minutes, SmokeyNet can be used for automated early notification of wildfires, providing a useful tool in the fight against destructive wildfires. 

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5. Wildfire smoke impacts lake ecosystems

   https://doi.org/10.1111/gcb.17367  

   Farruggia, Mary_Jade; Brahney, Janice; Tanentzap, Andrew_J; Brentrup, Jennifer_A; Brighenti, Ludmila_S; Chandra, Sudeep; Cortés, Alicia; Fernandez, Rocio_L; Fischer, Janet_M; Forrest, Alexander_L; et al (June 2024, Global Change Biology)

   Abstract Wildfire activity is increasing globally. The resulting smoke plumes can travel hundreds to thousands of kilometers, reflecting or scattering sunlight and depositing particles within ecosystems. Several key physical, chemical, and biological processes in lakes are controlled by factors affected by smoke. The spatial and temporal scales of lake exposure to smoke are extensive and under‐recognized. We introduce the concept of the lake smoke‐day, or the number of days any given lake is exposed to smoke in any given fire season, and quantify the total lake smoke‐day exposure in North America from 2019 to 2021. Because smoke can be transported at continental to intercontinental scales, even regions that may not typically experience direct burning of landscapes by wildfire are at risk of smoke exposure. We found that 99.3% of North America was covered by smoke, affecting a total of 1,333,687 lakes ≥10 ha. An incredible 98.9% of lakes experienced at least 10 smoke‐days a year, with 89.6% of lakes receiving over 30 lake smoke‐days, and lakes in some regions experiencing up to 4 months of cumulative smoke‐days. Herein we review the mechanisms through which smoke and ash can affect lakes by altering the amount and spectral composition of incoming solar radiation and depositing carbon, nutrients, or toxic compounds that could alter chemical conditions and impact biota. We develop a conceptual framework that synthesizes known and theoretical impacts of smoke on lakes to guide future research. Finally, we identify emerging research priorities that can help us better understand how lakes will be affected by smoke as wildfire activity increases due to climate change and other anthropogenic activities. 

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