Intercomparison of Fire Size, Fuel Loading, Fuel Consumption, and Smoke Emissions Estimates on the 2006 Tripod Fire, Washington, USA

Stacy A Drury,Narasimhan Sim Larkin,Theresa E O’Brien,Erin M Banwell,Sean M Raffuse,Shihming Huang,Scott J Strenfel,Tara T Strand

doi:10.4996/fireecology.1001056

Stacy A Drury, Narasimhan Sim Larkin + Show 6 more

Open Access

https://doi.org/10.4996/fireecology.1001056

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Abstract

AbstractLand managers rely on prescribed burning and naturally ignited wildfires for ecosystem management, and must balance trade-offs of air quality, carbon storage, and ecosystem health. A current challenge for land managers when using fire for ecosystem management is managing smoke production. Smoke emissions are a potential human health hazard due to the production of fine particulate matter (PM2.5), carbon monoxide (CO), and ozone (O3) precursors. In addition, smoke emissions can impact transportation safety and contribute to regional haze issues. Quantifying wildland fire emissions is a critical step for evaluating the impact of smoke on human health and welfare, and is also required for air quality modeling efforts and greenhouse gas reporting. Smoke emissions modeling is a complex process that requires the combination of multiple sources of data, the application of scientific knowledge from divergent scientific disciplines, and the linking of various scientific models in a logical, progressive sequence. Typically, estimates of fire size, available fuel loading (biomass available to burn), and fuel consumption (biomass consumed) are needed to calculate the quantities of pollutants produced by a fire. Here we examine the 2006 Tripod Fire Complex as a case study for comparing alternative data sets and combinations of scientific models available for calculating fire emissions. Specifically, we use five fire size information sources, seven fuel loading maps, and two consumption models (Consume 4.0 and FOFEM 5.7) that also include sets of emissions factors. We find that the choice of fuel loading is the most critical step in the modeling pathway, with different fuel loading maps varying by 108 %, while fire size and fuel consumption show smaller variations (36 % and 23 %, respectively). Moreover, we find that modeled fuel loading maps likely underestimate the amount of fuel burned during wildfires as field assessments of total woody fuel loading were consistently higher than modeled fuel loadings in all cases. The PM2.5 emissions estimates from Consume and FOFEM vary by 37 %. In addition, comparisons with available observational data demonstrate the value of using local data sets where possible.

Highlights

Ignited wildfires and prescribed fires play a key ecological role by regulating species composition, forest structure, hazardous fuels, and species regeneration in many wildland ecosystems (Weaver 1951, Cooper 1960, Agee 1998)
Total fuel consumption estimated by First Order Fire Effects Model (FOFEM) (56.8 Mg ha-1) was slightly lower than the Monitoring Trends in Burn Severity (MTBS) total of 59.7 Mg ha-1, while total fuel consumption estimated by Consume (71.4 Mg ha-1) was higher than the MTBS total
Comparisons of individual fuel types across the landscape indicated that Consume tended to estimate higher fuel consumption than MTBS for the closed conifer fuel types with more biomass available to burn, while Consume-based fuel consumption rates were generally lower than MTBS for the more open stand types

Summary

Introduction

Ignited wildfires and prescribed fires play a key ecological role by regulating species composition, forest structure, hazardous fuels, and species regeneration in many wildland ecosystems (Weaver 1951, Cooper 1960, Agee 1998). Smoke emissions from adding more fire to the landscape constitute a potential human health hazard due to the production of harmful pollutants such as finegrained particulate matter (particles ≤2.5 microns in diameter, or PM2.5), carbon monoxide (CO), and ozone (O3) precursors (Hardy et al 2001, Reinhardt and Ottmar 2004, Larkin et al 2009, Ottmar et al 2009, Koichi et al 2010) Such fires affect human welfare by contributing to regional haze, reducing visibility, and increasing concentrations of greenhouse gases. The Ottmar et al (2009) review further suggests that reducing uncertainty in the fuel characterization and fuel consumption steps will reduce uncertainty in smoke emissions modeling across scales (global, national, regional, single fire) and fire types (wildfire or prescribed fire). French et al (2011) suggested a causal relationship, with higher fuel loadings leading to higher fuel consumption and higher carbon emissions

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