The Alaska Reference Database originated as the standalone Alaska Fire Effects Reference Database, a ProCite reference database maintained by former BLM-Alaska Fire Service Fire Ecologist Randi Jandt. It was expanded under a Joint Fire Science Program grant for the FIREHouse project (The Northwest and Alaska Fire Research Clearinghouse). It is now maintained by the Alaska Fire Science Consortium and FRAMES, and is hosted through the FRAMES Resource Catalog. The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.
Type
Topic
Year
Displaying 201 - 225 of 276
Xu, Eisenhauer, Pellegrini, Wang, Certini, Guerra, Lai
Fire is a very common disturbance in terrestrial ecosystems and can give rise to significant effects on soil carbon (C) cycling and storage. Here, we conducted a global meta-analysis on the response of soil C cycling and storage across soil profiles (organic layer, 0-5 cm, 0-10…
Year: 2022
Type: Document
Source: FRAMES
Khan, Ghassemi
Growing wildfire-related transmission and distribution line outages have become a severe problem and a main concern for some utilities. This manuscript aims to integrate wildfire risk with the vulnerability of overhead lines through a probabilistic approach where a combined line…
Year: 2022
Type: Document
Source: FRAMES
Bailon-Ruiz, Bit-Monnot, Lacroix
This paper introduces a wildfire monitoring system based on a fleet of Unmanned Aerial Vehicles (UAVs) to provide firefighters with precise and up-to-date information about a propagating wildfire, so that they can devise efficient suppression actions. We present an approach to…
Year: 2022
Type: Document
Source: FRAMES
Le, Kim, Bae
Wildfires alter the composition and structure of ecosystems and result in huge economic costs. While future fires and ecosystems recovery might become increasingly challenging to manage under warming environment, further understanding of the main drivers of wildfires is…
Year: 2022
Type: Document
Source: FRAMES
Douglas, Jorgenson, Genet, Marcot, Nelsen
Climate change and intensification of disturbance regimes are increasing the vulnerability of interior Alaska Department of Defense (DoD) training ranges to widespread land cover and hydrologic changes. This is expected to have profound impacts on wildlife habitats, conservation…
Year: 2022
Type: Document
Source: FRAMES
Vachula, Liang, Sae-Lim, Xie
Recent fire events in Alaskan tundra ecosystems have been identified as harbingers of climate change and have caused reassessment of more traditional thinking about fire activity in this high-latitude biome. Although some work has demonstrated the novelty of these fires and…
Year: 2022
Type: Document
Source: FRAMES
Foster, Shuman, Rogers, Walker, Mack, Bourgeau-Chavez, Veraverbeke, Goetz
Forest characteristics, structure, and dynamics within the North American boreal region are heavily influenced by wildfire intensity, severity, and frequency. Increasing temperatures are likely to result in drier conditions and longer fire seasons, potentially leading to more…
Year: 2022
Type: Document
Source: FRAMES
Yi, Chen, Moghaddam, Kimball, Jones, Jandt, Miller, Miller
We used full-polarimetric L-band and P-band synthetic aperture radar (SAR) data collected from the recent NASA Arctic Boreal Vulnerability Experiment (ABoVE) airborne campaign and Sentinel-1 C-band dual-polarization data to understand the sensitivity of radar backscatter…
Year: 2022
Type: Document
Source: FRAMES
Bowring, Jones, Ciais, Guenet, Abiven
Recently identified post-fire carbon fluxes indicate that, to understand whether global fires represent a net carbon source or sink, one must consider both terrestrial carbon retention through pyrogenic carbon production and carbon losses via multiple pathways. Here these legacy…
Year: 2022
Type: Document
Source: FRAMES
Balch, Abatzoglou, Joseph, Koontz, Mahood, McGlinchy, Cattau, Williams
Night-time provides a critical window for slowing or extinguishing fires owing to the lower temperature and the lower vapour pressure deficit (VPD). However, fire danger is most often assessed based on daytime conditions1,2, capturing what promotes fire spread rather than what…
Year: 2022
Type: Document
Source: FRAMES
Demange, Di Fonso, Di Stefano, Vittorini
In the last decade, wildfires have become wider and more destructive. Climate change and the growth of urban areas are among the main factors that increase the risk of large-scale fires. This risk can be lowered with preventive measures. Among them, firefighting lines are used…
Year: 2022
Type: Document
Source: FRAMES
Clark
Aircraft play vital roles in managing wildfire, but their use is both costly and inherently risky. On average, USDA Forest Service aviation costs represent 30 percent of annual firefighting expenditures. And despite improvements in airworthiness and safety in the last decade,…
Year: 2022
Type: Document
Source: FRAMES
González, González-Trujillo, Muñoz, Armenteras
Fire is a natural agent with a paramount role in ecosystem functioning and biodiversity maintenance. Still, it can also act as a negative force against many ecosystems. Despite some knowledge of the interactions of fire and vegetation, there is no clear understanding of how…
Year: 2022
Type: Document
Source: FRAMES
Edalati-nejad, Ghodrat, Fanaee, Simeoni
This paper presents an investigation on the effect of fire intensity of a wind driven surface fire, similar to a large wildfire, on an idealized structure located downstream from the fire source. A numerical simulation was conducted using an open source CFD code called FireFOAM…
Year: 2022
Type: Document
Source: FRAMES
Bot, Borges
Wildfires threaten and kill people, destroy urban and rural property, degrade air quality, ravage forest ecosystems, and contribute to global warming. Wildfire management decision support models are thus important for avoiding or mitigating the effects of these events. In this…
Year: 2022
Type: Document
Source: FRAMES
Xiao, Feng, Li
As an inherent element of the Earth’s ecosystem, forest and vegetation fires are one of the key contributors to and direct consequences of climate change. Given that topography is one of the key drivers of forest landscapes and fire behavior, it is important to clarify what the…
Year: 2022
Type: Document
Source: FRAMES
Wu, Xu, McCarter, Zhang, Ganzoury, Waddington, de Lannoy
Pollutant leaching from wildfire-impacted peatland soils (peat) is well-known, but often underestimated when considering boreal ecosystem source water protection and when treating source waters to provide clean drinking water. Burning peat impacts its physical properties and…
Year: 2022
Type: Document
Source: FRAMES
Masrur, Taylor, Harris, Barnes, Petrov
Although the link between climate change and tundra fire activity is well-studied, we lack an understanding of how fire, vegetation, and topography interact to either amplify or dampen climatic effects on these tundra fires at Pan-Arctic scale. This study investigated the…
Year: 2022
Type: Document
Source: FRAMES
Palm, Suitor, Joly, Herriges, Kelly, Hervieux, Russell, Bentzen, Larter, Hebblewhite
Climate change will lead to more frequent and more severe fires in some areas of boreal forests, affecting the distribution and availability of late-successional forest communities. These forest communities help protect globally significant carbon reserves beneath permafrost…
Year: 2022
Type: Document
Source: FRAMES
Phillips, Rogers, Elder, Cooperdock, Moubarak, Randerson, Frumhoff
Wildfires in boreal forests release large quantities of greenhouse gases to the atmosphere, exacerbating climate change. Here, we characterize the magnitude of recent and projected gross and net boreal North American wildfire carbon dioxide emissions, evaluate fire management as…
Year: 2022
Type: Document
Source: FRAMES
Schuur, Abbott, Commane, Ernakovich, Euskirchen, Hugelius, Grosse, Jones, Koven, Leshyk, Lawrence, Loranty, Mauritz, Olefeldt, Natali, Rodenhizer, Salmon, Schädel, Strauss, Treat, Turetsky
Rapid Arctic environmental change affects the entire Earth system as thawing permafrost ecosystems release greenhouse gases to the atmosphere. Understanding how much permafrost carbon will be released, over what time frame, and what the relative emissions of carbon dioxide and…
Year: 2022
Type: Document
Source: FRAMES
Frumhoff, Phillips, Rogers
[Last paragraph of the opinion] We cannot stop global warming without dramatically reducing and ultimately eliminating fossil fuel emissions. But we also must keep boreal wildfire emissions in check. We ignore these wildfires and their accelerating climate impacts at our peril.…
Year: 2022
Type: Document
Source: FRAMES
Macander, Nelson, Nawrocki, Frost, Orndahl, Palm, Wells, Goetz
Widespread changes in the distribution and abundance of plant functional types (PFTs) are occurring in Arctic and boreal ecosystems due to the intensification of disturbances, such as fire, and climate-driven vegetation dynamics, such as tundra shrub expansion. To understand how…
Year: 2022
Type: Document
Source: FRAMES
Jorgenson, Kanevskiy, Roland, Hill, Schirokauer, Stehn, Schroeder, Shur
Permafrost formation and degradation creates a highly patchy mosaic of boreal peatland ecosystems in Alaska driven by climate, fire, and ecological changes. To assess the biophysical factors affecting permafrost dynamics, we monitored permafrost and ecological conditions in…
Year: 2022
Type: Document
Source: FRAMES
Burnett, Schütte, Harms
A warming climate combined with frequent and severe fires cause permafrost to thaw, especially in the region of discontinuous permafrost, where soil temperatures may only be a few degrees below 0 °C. Soil thaw releases carbon and nitrogen into the actively cycling pools, and…
Year: 2022
Type: Document
Source: FRAMES