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 The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.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 2151 - 2164 of 2164
Lewandrowski, Kim, Aillery
Economic studies have demonstrated that agricultural landowners could mitigate significant quantities of greenhouse gas (GHG) emissions through afforestation. The associated carbon, however, must remain stored in soils or biomass for several decades to achieve substantial…
Year: 2014
Type: Document
Source: FRAMES, TTRS
Lukenbach, Devito, Kettridge, Petrone, Waddington
Wildfire is the largest disturbance affecting northern peatlands; however, little is known about how burn severity (organic soil depth of burn) alters post-fire hydrological conditions that control the recovery of keystone peatland mosses (i.e. Sphagnum). For this reason, we…
Year: 2016
Type: Document
Source: FRAMES, TTRS
Attiwill, Binkley
In many parts of the world both the area and intensity of wild-land fires have increased alarmingly. Not only are fires increasing in number, but the nature of these fires is also changing. We see mega-fires of increasing size and intensity in many parts of the world including…
Year: 2013
Type: Document
Source: FRAMES, TTRS
Rocha, Shaver
Burned landscapes present several challenges to quantifying landscape carbon balance. Fire scars are composed of a mosaic of patches that differ in burn severity, which may influence postfire carbon budgets through damage to vegetation and carbon stocks. We deployed three eddy…
Year: 2011
Type: Document
Source: FRAMES, TTRS
Flannigan, Krawchuk, de Groot, Wotton, Gowman
Wildland fire is a global phenomenon, and a result of interactions between climate-weather, fuels and people. Our climate is changing rapidly primarily through the release of greenhouse gases that may have profound and possibly unexpected impacts on global fire activity. The…
Year: 2009
Type: Document
Source: FRAMES
Seiler, Crutzen
In order to estimate the production of charcoal and the atmospheric emissions of trace gases volatilized by burning we have estimated the global amounts of biomass which are affected by fires. We have roughly calculated annual gross burning rates ranging between about 5 Pg and 9…
Year: 1980
Type: Document
Source: FRAMES, TTRS
Wang, Bond-Lamberty, Gower
The objective of this study was to quantify carbon (C) distribution for boreal black spruce (Picea mariana (Mill.) BSP) stands comprising a fire chronosequence in northern Manitoba, Canada. The experimental design included seven well-drained (dry) and seven poorly-drained (wet)…
Year: 2003
Type: Document
Source: FRAMES, TTRS
Payne, Stocks, Robinson, Wasey, Strapp
Combustion aerosol particles from boreal forest fires were quantified to facilitate investigation of the potential effects of increased fire activity caused by global warming, by providing data inputs for global and regional climate modelling of the direct and indirect effects.…
Year: 2004
Type: Document
Source: FRAMES, TTRS
Kasischke, Christensen, Stocks
Fire strongly influences carbon cycling and storage in boreal forests. In the near-term, if global warming occurs, the frequency and intensity of fires in boreal forests are likely to increase significantly. A sensitivity analysis on the relationship between fire and carbon…
Year: 1995
Type: Document
Source: FRAMES, TTRS
Gromtsev
Fire layers in peat columns from bogs, and carbon layers in soil trenches on dry ground were used to analyse the pattern of occurrence of fires in natural spruce [Picea abies] and pine [Pinus sylvestris] boreal forests of Karelia during the last 3000-6000 years. Results of the…
Year: 1993
Type: Document
Source: FRAMES
Czimczik, Schmidt, Schulze
Fires in boreal forests frequently convert organic matter in the organic layer to black carbon, but we know little of how changing fire frequency alters the amount, composition and distribution of black carbon and organic matter within soils, or affects podzolization. We…
Year: 2005
Type: Document
Source: FRAMES, TTRS
Finer, Messier, Degrandpré
Fine-root (diameter 10 mm) standing biomass, length, distribution, production, and decomposition were studied in mixed conifer/broadleaved forest stands 48, 122, and 232 yr after fire on clay soils in the southern boreal forest of Quebec. A combination of ingrowth bags, soil…
Year: 1997
Type: Document
Source: FRAMES, TTRS
Tidwell, Brown
From the text ... 'One way to protect the WUI is to restore surrounding landscapes to a healthy, resilient condition. Healthy, resilient forest ecosystems are less likely to see uncharacteristically severe wildfires that turn into human and ecological disasters. The USDA Forest…
Year: 2010
Type: Document
Source: TTRS
Bowman, Balch, Artaxo, Bond, Carlson, Cochrane, D'Antonio, DeFries, Doyle, Harrison, Johnston, Keeley, Krawchuk, Kull, Marston, Moritz, Prentice, Roos, Scott, Swetnam, Van der Werf, Pyne
Fire is a worldwide phenomenon that appears in the geological record soon after the appearance of terrestrial plants. Fire influences global ecosystem patterns and processes, including vegetation distribution and structure, the carbon cycle, and climate. Although humans and fire…
Year: 2009
Type: Document
Source: FRAMES, TTRS