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 The database provides a listing of fire research publications relevant to Alaska and a venue for sharing unpublished agency reports and works in progress that are not normally found in the published literature.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 6168
Dockry, Hoagland, Leighton, Durglo, Pradhananga
Native American and Alaska Native tribes manage millions of acres of land and are leaders in forestry and fire management practices despite inadequate and inequitable funding. Native American tribes are rarely considered as research partners due to historically poor…
Year: 2023
Type: Document
Source: FRAMES
Baillargeon, Pold, Natali, Sistla
The Arctic is experiencing the greatest increase in average surface temperature globally, which is projected to amplify wildfire frequency and severity. Wildfire alters the biogeochemical characteristics of arctic ecosystems. However, the extent of these changes over time—…
Year: 2022
Type: Document
Source: FRAMES
Moyo
Globally, wildfires and prescribed fires are becoming more prevalent and are known to affect plant and animals in diverse ecosystems. Understanding the responses of animal communities to fire is a central issue in conservation and a panacea to predicting how fire regimes may…
Year: 2022
Type: Document
Source: FRAMES
To collect partner and employee input on the Wildfire Crisis Strategy 10-year Implementation Plan, the Forest Service and National Forest Foundation hosted a series of roundtable discussions in the winter and spring of 2022. Individual roundtables were focused on each of the…
Year: 2022
Type: Document
Source: FRAMES
Fox, Holman, Rigo, Al Suwaidi, Grice
Polycyclic Aromatic Hydrocarbons (PAHs) are routinely used as proxies for wildfire in geological sediments associated with large igneous province (LIP) driven CO2 increases and mass extinction events. One example is the end-Triassic mass extinction event (ETE) driven by Earth's…
Year: 2022
Type: Document
Source: FRAMES
Hewitt, Day, DeVan, Taylor
Root-associated fungi play a critical role in plant ecophysiology, growth, and subsequent responses to disturbances, so they are thought to be particularly instrumental in shaping vegetation dynamics after fire in the boreal forest. Despite increasing data on the distribution of…
Year: 2023
Type: Document
Source: FRAMES
Bieber, Vyas, Koltz, Burkle, Bey, Guzinski, Murphy, Vidal
1. Animal ecology and evolution are shaped by environmental perturbations, which are undergoing unprecedented alterations due to climate change. Fire is one such perturbation that causes significant disruption by causing mortality and altering habitats and resources for animals…
Year: 2023
Type: Document
Source: FRAMES
Kuzmina, Lim, Loiko, Pokrovsky
Extensive studies have been performed on wildfire impact on terrestrial and aquatic ecosystems in the taiga biome, however consequences of wildfires in the tundra biome remain poorly understood. In such a biome, permafrost peatlands occupy a sizable territory in the Northern…
Year: 2022
Type: Document
Source: FRAMES
Volokitina, Korets, Sofronova
To study the vegetation affected by fires and to create databases useful for fire behavior prediction, three methodological approaches are used: (1) selective, (2) standard, and (3) individual-standard. The selective method consists of empirically studying the drying and…
Year: 2022
Type: Document
Source: FRAMES
Nolan, Anderson, Poulter, Varner
Aim: Each year, wild and managed fires burn roughly 4 million km2 [~400 million hectares (Mha)] of savanna, forest, grassland and agricultural ecosystems. Land use and climate change have altered fire regimes throughout the world, with a trend toward higher-severity fires found…
Year: 2022
Type: Document
Source: FRAMES
Feltrin, Smith, Adams, Thompson, Kolden, Yedinak, Johnson
Disruption of photosynthesis and carbon transport due to damage of the tree crown and stem cambial cells, respectively, can cause tree mortality. It has recently been proposed that fire-induced dysfunction of xylem plays an important role in tree mortality. Here, we…
Year: 2023
Type: Document
Source: FRAMES
Fettig, Runyon, Homicz, James, Ulyshen
Purpose of Review
Fire and insects are major disturbances in North American forests. We reviewed literature on the effects of fire on bark beetles, defoliators, and pollinators, as well as on the effects of bark beetle and defoliator epidemics on fuels and wildfires.
Recent…
Year: 2022
Type: Document
Source: FRAMES
Liu, Zhang
In this article, we propose a mathematical model for insect outbreaks coupled with wildfire disturbances and an optimization model for finding suitable wildfire frequencies. We use a refined Holling II function as a model for the nonlinear response of fire frequency against…
Year: 2022
Type: Document
Source: FRAMES
Schumaker, Watkins, Heinrichs
As fire frequency and severity grow throughout the world, scientists working across a range of disciplines will increasingly need to incorporate wildfire models into their research. However, fire simulators tend to be highly complex, time-consuming to learn, and difficult to…
Year: 2022
Type: Document
Source: FRAMES
Jones, Ayars, Parks, Chmura, Cushman, Sanderlin
Purpose of Review: Climate change will continue to alter spatial and temporal variation in fire characteristics, or pyrodiversity. The causes of pyrodiversity and its consequences for biological communities are emerging as a promising research area with great potential for…
Year: 2022
Type: Document
Source: FRAMES
Liu, Yang
Fire frequency and intensity are increasing due to higher temperatures and more droughts. The distributions of fuels (vegetation in natural conditions) are also changing in response to climate change. The vegetation in cold environments such as high latitudes and high altitudes…
Year: 2022
Type: Document
Source: FRAMES
Bousquet, Mialon, Rodriguez-Fernandez, Mermoz, Kerr
Anthropogenic climate change is now considered to be one of the main factors causing an increase in both the frequency and severity of wildfires. These fires are prone to release substantial quantities of CO2 into the atmosphere and to endanger natural ecosystems and…
Year: 2022
Type: Document
Source: FRAMES
Jorgenson, Brown, Hiemstra, Genet, Marcot, Murphy, Douglas
Alaska has diverse boreal ecosystems across heterogeneous landscapes driven by a wide range of biological and geomorphic processes associated with disturbance and successional patterns under a changing climate. To assess historical patterns and rates of change, we quantified the…
Year: 2022
Type: Document
Source: FRAMES
Liu, Riley, Keenan, Mekonnen, Holm, Zhu, Torn
Arctic shrub expansion alters carbon budgets, albedo, and warming rates in high latitudes but remains challenging to predict due to unclear underlying controls. Observational studies and models typically use relationships between observed shrub presence and current environmental…
Year: 2022
Type: Document
Source: FRAMES
Lamont
The interaction effects between climate and fire regime in controlling the type of vegetation and species composition is well established among the Earth’s biomes. Climate and the associated fire regime are never stable for long, and annual temperatures, atmospheric carbon…
Year: 2022
Type: Document
Source: FRAMES
Smith, Lamborn
In a rapidly changing environment where fires are becoming more frequent and severe, we need information and tools that can help us understand the broad scope of impacts fire can have in complex social-ecological systems. Taking a novel approach, we used a social-ecological…
Year: 2022
Type: Document
Source: FRAMES
Harvey, Enright
Extreme fire seasons in both hemispheres in 2019 and 2020 have highlighted the strong link between climate warming and altered fire regimes. While shifts in fire regimes alone can drive profound changes in plant populations, communities, and ecosystems, the direct effects of…
Year: 2022
Type: Document
Source: FRAMES
Zolkos, MacDonald, Hung, Schade, Ludwig, Mann, Treharne, Natali
Northern high-latitude deltas are hotspots of biogeochemical processing, terrestrial-aquatic connectivity, and, in Alaska’s Yukon-Kuskokwim Delta (YKD), tundra wildfire. Yet, wildfire effects on aquatic biogeochemistry remain understudied in northern delta regions, thus limiting…
Year: 2022
Type: Document
Source: FRAMES
Zhang, Wang, Liu
Wildfires not only severely damage the natural environment and global ecological balance but also cause substantial losses to global forest resources and human lives and property. Unprecedented fire events such as Australia's bushfires have alerted us to the fact that wildfire…
Year: 2022
Type: Document
Source: FRAMES
Zhou, Biro, Wong, Batterman, Staver
The biogeochemical signature of fire shapes the functioning of many ecosystems. Fire changes nutrient cycles not only by volatilizing plant material, but also by altering organic matter decomposition—a process regulated by soil extracellular enzyme activities (EEAs). However,…
Year: 2022
Type: Document
Source: FRAMES