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 The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.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 1 - 25 of 38
Guiterman, Lynch, Axelson
We present a new R package to provide dendroecologists with tools to infer, quantify, analyze, and visualize growth suppression events in tree rings. dfoliatR is based on the OUTBREAK program and builds on existing resources in the R computing environment and the well-used dplR…
Year: 2020
Type: Document
Source: FRAMES
Bowman, Kolden, Abatzoglou, Johnston, Van der Werf, Flannigan
Vegetation fires are an essential component of the Earth system but can also cause substantial economic losses, severe air pollution, human mortality and environmental damage. Contemporary fire regimes are increasingly impacted by human activities and climate change, but, owing…
Year: 2020
Type: Document
Source: FRAMES
Pyne
Dr. Stephen Pyne, the world's foremost fire historian, discusses how we are living in a Fire Age of comparable scale to the Ice Ages of the Pleistocene, and whether our relationship with fire is a mutual assistance pact or a Faustian bargain. To read his responses to the…
Year: 2020
Type: Media
Source: FRAMES
Pyne
Fire offers a special perspective by which to understand the Earth being remade by humans. Fire is integrative, so intrinsically interdisciplinary. Fire use is unique to humans, so a tracer of humanity's ecological impacts. Anthropogenic fire history shows the long influence of…
Year: 2020
Type: Document
Source: FRAMES
Healey, Yang, Cohen
he Landscape Change Monitoring System (LCMS) is a remote sensing-based system for mapping and monitoring landscape change across the United States. LCMS produces annual maps depicting change (vegetation loss and vegetation gain), land cover, and land use from 1985 to present…
Year: 2020
Type: Tool
Source: FRAMES
Cartledge
[no description entered]
Year: 1996
Type: Document
Source: TTRS
Pippin, Nichols
[no description entered]
Year: 1996
Type: Document
Source: TTRS
Foxx
[no description entered]
Year: 1996
Type: Document
Source: TTRS
Ibarra-F, Martin-R, Cox, Miranda-Z.
Vegetational changes were measured after 27 prescribed burns and 3 wildfires which occurred from 1982 to 1995 on buffelgrass pastures highly infested with brush in Sonora, Mexico. Densities of most undesirable brush species were reduced from 40 to 60% with fire. When prescribed…
Year: 1996
Type: Document
Source: TTRS
Rogers, Balch, Goetz, Lehmann, Turetsky
Fire is a complex Earth system phenomenon that fundamentally affects vegetation distributions, biogeochemical cycling, climate, and human society across most of Earth's land surface. Fire regimes are currently changing due to multiple interacting global change drivers, most…
Year: 2020
Type: Document
Source: FRAMES
Frost, Loehman, Saperstein, Macander, Nelson, Paradis, Natali
Alaska's Yukon-Kuskokwim Delta (YKD) is one of the warmest parts of the Arctic tundra biome and tundra fires are common in its upland areas. Here, we combine field measurements, Landsat observations, and quantitative cover maps for tundra plant functional types (PFTs) to…
Year: 2020
Type: Document
Source: FRAMES
Vachula, Sae-Lim, Russell
Extensive burning of Arctic tundra landscapes in recent years has contradicted the conventional view that fire is a rare, spatially limited disturbance in tundra. These fires have been identified as harbingers of climate change, despite our limited understanding of Arctic fire…
Year: 2020
Type: Document
Source: FRAMES
Pyne
Humanity’s fire practices are creating the fire equivalent of an ice age. Our shift from burning living landscapes to burning lithic ones is affecting all aspects of Earth.
Year: 2020
Type: Media
Source: FRAMES
Flanagan
This webinar will review recent research led by Duke University investigating the impacts of fire on peatland ecosystems. Severe wildfires can cause smoldering ground fires that oxidize entire carbon stores and threaten peatlands around the globe. However, low‐severity surface…
Year: 2020
Type: Media
Source: FRAMES
Karp, Holman, Hopper, Grice, Freeman
Polycyclic aromatic hydrocarbons (PAHs), produced via incomplete combustion of organics, convey signatures of vegetation burned in the geologic past. New and published burn experiments reveal how the quantity, distributions, and isotopic abundances of fire-derived PAHs were…
Year: 2020
Type: Document
Source: FRAMES
Jandt, Thoman
This AFSC research brief takes a look at early Alaska fire history from the 1940s. The "Zombie" Fires of 1942 is a historical narrative of an exceptional fire event related to the Alaska Railroad, including an early description of a holdover fire burning over winter.
Year: 2020
Type: Document
Source: FRAMES
The Fire Continuum Conference, co-sponsored by the Association for Fire Ecology and the International Association of Wildland Fire, was designed to cover both the biophysical and human dimensions aspects of fire along the fire continuum. This proceedings includes many of topics…
Year: 2020
Type: Document
Source: FRAMES
Inglis, Vukomanovic
Fire management in protected areas faces mounting obstacles as climate change alters disturbance regimes, resources are diverted to fighting wildfires, and more people live along the boundaries of parks. Evidence-based prescribed fire management and improved communication with…
Year: 2020
Type: Document
Source: FRAMES
Hoecker, Higuera, Kelly, Hu
Boreal forest and tundra biomes are key components of the Earth system because the mobilization of large carbon stocks and changes in energy balance could act as positive feedbacks to ongoing climate change. In Alaska, wildfire is a primary driver of ecosystem structure and…
Year: 2020
Type: Document
Source: FRAMES
Abrams
Approximately 30 Quercus (oak) species occur in the eastern United States, of which Q alba, Q rubra, Q velutina, Q coccinea, Q stellata and Q prinus are among the most dominant. Quercus distribution greatly increased at the beginning of the Holocene epoch (10 000 years BP), but…
Year: 1996
Type: Document
Source: TTRS
Ottmar, Schaaf, Alvarado
From the Introduction...'Fire is the single most important ecological disturbance process throughout the interior Pacific Northwest (Mutch and others 1993; Agee 1994). It is also a natural process that helps maintain a diverse ecological landscape. Fire suppression and timber…
Year: 1996
Type: Document
Source: TTRS
From the Summary by Dennis Knight (p.233-235) ... 'During and after the 1988 fires, there were many predictions on how greater Yellowstone area (GYA) ecosystems would be affected. Some were based on research that had been done previously; others stemmed more from anecdotal…
Year: 1996
Type: Document
Source: TTRS
Hu, Brubaker, Anderson
Analyses of pollen, plant macrofossils, macroscopic charcoal, mollusks, magnetic susceptibility, and geochemical content of a sediment core from Farewell Lake yield a 11,000-yr record of terrestrial and aquatic ecosystem changes in the northwestern foothills of the Alaska Range…
Year: 1996
Type: Document
Source: FRAMES