Bacterial Emission Factors: A Foundation for the Terrestrial-Atmospheric Modeling of Bacteria Aerosolized by Wildland Fires

Kobziar, Leda N.; Lampman, Phinehas; Tohidi, Ali; Kochanski, Adam K.; Cervantes, Antonio; Hudak, Andrew T.; McCarley, Ryan; Gullett, Brian; Aurell, Johanna; Moore, Rachel; Vuono, David C.; Christner, Brent C.; Watts, Adam C.; Cronan, James; Ottmar, Roger

doi:10.1021/acs.est.3c05142

Cited by 3 publications

(1 citation statement)

References 49 publications

(127 reference statements)

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“…74 Similarly, Kobziar et al have recently shown for the first time that large amounts of microbial biomass is emitted from wildland fires and transported long distances in air with potential health consequences to ecosystems and humans. 75…”

Section: Linkages To Climate Researchmentioning

confidence: 99%

Cross-cutting research and future directions under the GAPS networks

Harner,

Saini,

Shahpoury

et al. 2024

Environ. Sci.: Adv.

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Section: Linkages To Climate Researchmentioning

confidence: 99%

Cross-cutting research and future directions under the GAPS networks

Harner,

Saini,

Shahpoury

et al. 2024

Environ. Sci.: Adv.

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Generating fuel consumption maps on prescribed fire experiments from airborne laser scanning

McCarley,

Hudak,

Bright

et al. 2024

Int. J. Wildland Fire

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Background Characterisation of fuel consumption provides critical insights into fire behaviour, effects, and emissions. Stand-replacing prescribed fire experiments in central Utah offered an opportunity to generate consumption estimates in coordination with other research efforts. Aims We sought to generate fuel consumption maps using pre- and post-fire airborne laser scanning (ALS) and ground measurements and to test the spatial transferability of the ALS-derived fuel models. Methods Using random forest (RF), we empirically modelled fuel load and estimated consumption from pre- and post-fire differences. We used cross-validation to assess RF model performance and test spatial transferability. Key results Consumption estimates for overstory fuels were more precise and accurate than for subcanopy fuels. Transferring RF models to provide consumption estimates in areas without ground training data resulted in loss of precision and accuracy. Conclusions Fuel consumption maps were produced and are available for researchers who collected coincident fire behaviour, effects, and emissions data. The precision and accuracy of these data vary by fuel type. Transferability of the models to novel areas depends on the user’s tolerance for error. Implications This study fills a critical need in the broader set of research efforts linking fire behaviour, effects, and emissions.

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Principles of fire ecology

Kobziar,

Hiers,

Belcher

et al. 2024

fire ecol

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Fire ecology is a complex discipline that can only be understood by integrating biological, physical, and social sciences. The science of fire ecology explores wildland fire’s mechanisms and effects across all scales of time and space. However, the lack of defined, organizing concepts in fire ecology dilutes its collective impact on knowledge and management decision-making and makes the discipline vulnerable to misunderstanding and misappropriation. Fire ecology has matured as a discipline and deserves an enunciation of its unique emergent principles of organization. Most scientific disciplines have established theories, laws, and principles that have been tested, debated, and adopted by the discipline’s practitioners. Such principles reflect the consensus of current knowledge, guide methodology and interpretation, and expose knowledge gaps in a coherent and structured way. In this manuscript, we introduce five comprehensive principles to define the knowledge fire ecology has produced and provide a framework to support the continued development and impact of the fire ecology discipline.

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Bacterial Emission Factors: A Foundation for the Terrestrial-Atmospheric Modeling of Bacteria Aerosolized by Wildland Fires

Cited by 3 publications

References 49 publications

Cross-cutting research and future directions under the GAPS networks

Cross-cutting research and future directions under the GAPS networks

Generating fuel consumption maps on prescribed fire experiments from airborne laser scanning

Principles of fire ecology

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