Alaska Reference Database

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 The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.

 

Filter Results

Displaying 1 - 9 of 9

In land change science studies, a cover type is defined by land surface attributes, specifically including the types of vegetation, topography and human structures, which makes it difficult to characterize land cover as discrete classes. One of the...

Person: Schneider, Fernando
Year: 2010
Resource Group: Document
Source: TTRS

Fire disturbance at high latitudes modifies a broad range of ecosystem properties and processes, thus it is important to monitor the response of vegetation to fire disturbance. This monitoring effort can be aided by lidar remote sensing, which captures...

Person: Goetz, Sun, Baccini, Beck
Year: 2010
Resource Group: Document
Source: TTRS

The Idaho Panhandle National Forests (IPNF), in partnership with the University of Idaho, the Fire Sciences Laboratory, and The Sampson Group, developed a Geographic Information System (GIS) based wildfire hazard-risk assessment. The assessment was...

Person: Neuenschwander, Ryan, Gollberg, Harkins, Morgan, Neuenschwander, Chrisman, Zack, Jacobson, Grant, Sampson
Year: 2000
Resource Group: Document
Source: TTRS

Fuel input layers for the FARSITE fire growth model were created for all lands in and around the Gila National Forest, New Mexico, using satellite imagery, terrain modeling, and biophysical simulation. FARSITE is a spatially explicit fire growth model...

Person: Neuenschwander, Ryan, Gollberg, Keane, Mincemoyer, Schmidt, Garner
Year: 2000
Resource Group: Document
Source: TTRS

Knowledge of temporal changes in the area burned by wildfires is required to understand their influence on global climate change. This paper reviews the primary methods of reconstructing and measuring area burned. The area burned by wildfires is...

Person: Innes, Verstraete, Larsen
Year: 2000
Resource Group: Document
Source: TTRS

Forest fires are not spatially uniform events. They result in a complicated mosaic of burned and unburned vegetation. To manage fuel loads and the associated fire hazard it is essential to improve our understanding of the spatial patterns of the...

Person: Medler
Year: 2000
Resource Group: Document
Source: TTRS

The fire season of 2000 is one of the most severe on record, burning approximately seven million acres by the end of September—over 2.5 times the 10-year average of 2.6 million acres. Fires burning in the wildland-urban interface have resulted in...

Person: Hesseln, Rideout
Year: 2000
Resource Group: Document
Source: TTRS

Aim: This paper describes the characteristics of the spatio-temporal distribution of vegetation fires as detected from satellite data for the 12 months April 1992 to March 1993. Location: Fires are detected daily at a spatial resolution of 1 km for all...

Person: Dwyer, Pereira, Gregoire, DaCamara
Year: 2000
Resource Group: Document
Source: FRAMES, TTRS

Visible and infrared (IR) observations of flame structure were made of the Frostfire controlled burn carried out 8-10 July 1999 at the Caribou-Poker Creek Research Watershed near Fairbanks, Alaska. The observations were taken from Caribou Peak, facing...

Person: Coen, Mahalingam, Milford, Clark, Daily
Year: 2000
Resource Group: Document
Source: FRAMES, TTRS