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 The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.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 108
Hessburg
We have all seen the news - hotter summers, and bigger, badder wildfires. What's going on? How did we get here? Paul tells a fast-paced story of western US forests - unintentionally yet massively changed by a century of management. He relates how these changes, coupled with a…
Year: 2017
Type: Media
Source: FRAMES
Finney
Why is calibrating the fire behavior models important to predicting fire behavior - an interview with Mark Finney a Research Scientist at the RMRS Fire Sciences Lab. Mark highlight's considerations an analyst should make when validating fire behavior models to fire behavior.
Year: 2017
Type: Media
Source: FRAMES
Finney
Why use FSPro - an interview with Mark Finney - This tool was developed to help inform risk based decisions associated with values at risk and probability of fire impacts to those values.
Year: 2017
Type: Media
Source: FRAMES
Finney
Mark Finney provides some considerations when setting up FSPro analyses - What is it you want to know from the analysis - is it the likely hood something is going to happen or is it the potential something is going to happen? These are different questions and the analyst can…
Year: 2017
Type: Media
Source: FRAMES
Lopes, Ribeiro, Viegas, Raposo
The present work addresses the problem of how wind should be taken into account in fire spread simulations. The study was based on the software system FireStation, which incorporates a surface fire spread model and a solver for the fluid flow (Navier-Stokes) equations. The…
Year: 2017
Type: Document
Source: TTRS
Jones, Berrens
Recent growth in the frequency and severity of US wildfires has led to more wildfire smoke and increased public exposure to harmful air pollutants. Populations exposed to wildfire smoke experience a variety of negative health impacts, imposing economic costs on society. However…
Year: 2017
Type: Document
Source: TTRS
Gould, Sullivan, Hurley, Koul
Different methods can be used to measure the time and distance of travel of a fire and thus its speed. The selection of a particular method will depend on the experimental objectives, design, scale, location (in the laboratory or field), required accuracy and resources available…
Year: 2017
Type: Document
Source: TTRS
Gharun, Possell, Bell, Adams
Fire plays a critical role in biodiversity, carbon balance, soil erosion, and nutrient and hydrological cycles. While empirical evidence shows that fuel reduction burning can reduce the incidence, severity and extent of unplanned fires in Australia and elsewhere, the integration…
Year: 2017
Type: Document
Source: TTRS
Brenkert-Smith, Meldrum, Champ, Barth
Wildfire and the threat it poses to society represents an example of the complex, dynamic relationship between social and ecological systems. Increasingly, wildfire adaptation is posited as a pathway to shift the approach to fire from a suppression paradigm that seeks to control…
Year: 2017
Type: Document
Source: TTRS
Butler, Marsh, Domitrovich, Helmkamp
Wildland fire fighting is a high-risk occupation requiring considerable physical and psychological demands. Multiple agencies publish fatality summaries for wildland firefighters; however, the reported number and types vary. At least five different surveillance systems capture…
Year: 2017
Type: Document
Source: TTRS
Balch, Bradley, Abatzoglou, Nagy, Fusco, Mahood
The economic and ecological costs of wildfire in the United States have risen substantially in recent decades. Although climate change has likely enabled a portion of the increase in wildfire activity, the direct role of people in increasing wildfire activity has been largely…
Year: 2017
Type: Document
Source: TTRS
Ziel
This guide offers recommendations for using Canadian Forest Fire Danger Rating System (CFFDRS) fuel moisture codes and fire behavior indices from the Fire Weather Index (FWI) system to provide objective guidance for initial settings for many analysis inputs to WFDSS and IFTDSS.…
Year: 2017
Type: Document
Source: FRAMES
Thompson, Calkin, Scott, Hand
Wildfire risk assessment is increasingly being adopted to support federal wildfire management decisions in the United States. Existing decision support systems, specifically the Wildland Fire Decision Support System (WFDSS), provide a rich set of probabilistic and risk‐based…
Year: 2017
Type: Document
Source: FRAMES
Ziel, Barnes, Stratton
"WFDSS Analyses: Getting Ready for the 2017 Season" webinar on May 17, 2017, organized by the Fire Modeling and Analysis Committee and presented by Rick Stratton, Jennifer Barnes, and Robert Ziel.
Year: 2017
Type: Media
Source: FRAMES
These tables calculate Dew Point and Relative Humidity based on the observed wet bulb and dry bulb temperatures and the elevation at the site of the observation.
Year: 2017
Type: Document
Source: FRAMES
McFayden
WeatherSHIELD (Short & Intermediate Ensemble & Long-term Dynamic Scenarios - Prototype) presented by Colin McFayden.
Year: 2017
Type: Media
Source: FRAMES
Strader, Jandt, Jenkins, York, Ziel
Presented by Heidi Strader, Randi Jandt, Jenn Jenkins, Alison York and Robert Ziel. Optional webinar for AFSC remote sensing workshop presenters to introduce the Alaska fire management context. We will summarize the natural history of fire in the state, explain how fire…
Year: 2017
Type: Media
Source: FRAMES
Stevens
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Ziel, Bulock, Wattenbarger, Weddle, Thompson, Bourgeau-Chavez, Leblon
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Seaman
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
McCorkle
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Thompson
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Huffman
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Jandt
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES
Stevens
From the Spring 2017 AFSC Remote Sensing Workshop: Opportunities to Apply Remote Sensing in Boreal/Arctic Wildfire Management and Science.
Year: 2017
Type: Media
Source: FRAMES