67 resources found

This paper analyzes the record-breaking 2023 wildfires in British Columbia, detailing their significant ecological and social impacts, which are seen as the result of a century of altered relationships with fire intensified by climate change. The authors argue for an urgent transformative shift towards coexisting with wildfire, moving beyond suppression to embrace its ecological role and Indigenous stewardship practices. The paper proposes six interrelated strategies to achieve this coexistence: diversifying wildfire response, increasing suppression capacity, mitigating community risk, implementing landscape fire management, transforming wildfire governance, and strengthening expertise. This paper emphasizes the need for a holistic, all-of-society approach involving policy changes, sustained funding, and collaboration to build resilience against future extreme wildfires.

This report addresses the critical issue of maintaining large, old trees in United States forests that historically experienced frequent fires but have been subjected to long periods of fire suppression. The document synthesizes existing research to understand how reintroducing fire through prescribed burning impacts these venerable trees, particularly concerning injury and mortality. It delves into the causes of tree death from fire, including heat damage to crowns, cambium, and roots, with a specific focus on the role of accumulated duff and subsequent bark beetle attacks. Furthermore, the report examines management options and treatment effects aimed at enhancing old tree resilience during prescribed burns, offering practical guidance on techniques like duff raking and burning under specific conditions, ultimately striving to balance ecological restoration with the conservation of these keystone forest components.

This paper details an experimental crown fire conducted in an Alberta, Canada, boreal black spruce forest to assess the effectiveness of recent crown thinning as a fuel treatment. Researchers ignited a 3. 6-hectare fire, observing its behavior in both untreated and thinned sections. The key finding was that while thinning led to a significant reduction in fire intensity, it did not reduce the fire's spread rate nor total fuel consumption. This suggests that in dense boreal black spruce with high surface fuel loads and low crown base heights, thinning alone may not prevent the rapid progression of crown fires, but it could potentially aid suppression efforts by reducing the intensity.

This paper explores operational resilience in western U. S. frequent-fire forests, emphasizing how historical forest structures fostered health and adaptability. The authors argue that very low tree densities prior to widespread fire suppression minimized competition, which in turn supported vigorous tree growth and greater resistance to stressors like drought and bark beetles. By comparing historical data with contemporary forest conditions using the Stand Density Index, the authors found a significant increase in tree density and competition today. This sugests that current management practices, which are focused primarily on fuel reduction, may not adequately restore the ecological resilience historically maintained by frequent, low-intensity fires. The paper advocates for a fundamental rethinking of forest management to prioritize significantly lower tree densities and minimal competition to enhance long-term forest health.

This study investigates the effects of forest thinning on the understory vegetation in ponderosa pine and Douglas-fir forests of south-central British Columbia. The study addresses the problem of forest in-growth due to fire suppression, which reduces grazing land and increases wildfire risk. Through a four-year data collection period at two sites, the researchers examined how thinning, which reduces tree density, impacts understory species diversity and biomass production. The findings indicate that while thinning may not consistently increase species diversity in the short term, it does lead to a significant increase in total understory biomass within a few years, suggesting its potential as a tool for ecological restoration and enhancing forage for livestock.

This LMH Document #79 outlines the principles and best practices for silvicultural systems in British Columbia, emphasizing a shift toward complex, multi-value forest management in the 21st century. Its primary purpose is to serve as a central reference and conceptual framework for forest professionals to design and implement silvicultural plans that move a stand from its current state to a desired future condition through planned interventions, known as stand development pathways. A crucial and recurring theme is the growing role of First Nations, including their traditional knowledge, values, and stewardship goals, which are integrated alongside ecological, social, and economic objectives. The document provides detailed guidance on technical aspects, such as managing for biodiversity, mitigating risks like windthrow and pests, and utilizing adaptive management for continuous improvement in forestry practices.

This document investigates the effectiveness of various thinning, pruning, and residue fuel management strategies designed to mitigate extreme wildfire hazards in the fire-prone forests of interior British Columbia. Using both simulated scenarios and analyses of actual operational treatments, the research modeled impacts on passive and active crown fire potential, as well as tree mortality. A key finding is that while removing small trees reduces the risk of passive crown fire, the concurrent removal of some larger trees is necessary to substantially reduce the threat of active crown fire. The study also confirmed that effective management of residue fuels is critical for treatment success, while pruning was found to have minimal impact on crown fire mitigation. This work provides valuable, region-specific data to help forest managers make informed wildfire management decisions regarding necessary treatment intensity.

This document introduces the concept of fire-smart forest management as a pragmatic approach to achieving sustainable forest management in Canada's fire-dominated ecosystems. The core challenge addressed is how to simultaneously minimize the socioeconomic impacts of fire while maximizing its ecological benefits, objectives that have historically been seen as contradictory. Fire-smart forest management integrates both forest and fire management activities, from stand to landscape levels, through proactive planning, such as altering forest fuels to reduce the potential for undesirable wildfires and lessen the risks associated with prescribed burning. This new paradigm is necessary because traditional aggressive fire suppression is reaching its maximum effectiveness, necessitating a shift in attitude to embrace fire's essential ecological role and mitigate its negative effects through integrated management strategies.

This webinar argues that managing the escalating crisis of high-severity Canadian wildfires requires a move beyond traditional fire suppression toward proactive fuel management. The key is to apply a strategic risk framework that prioritizes efforts based on both fire probability and the immense consequence to critical values at risk, such as vital infrastructure, vulnerable communities, and watersheds. Effective mitigation must combine mandated land-use regulations, such as strict FireSmart building standards, with a significant increase in landscape-level fuel treatments, including prescribed burning. The webinar discusses that achieving long-term success necessitates a fundamental reworking of the existing forest management framework in British Columbia to adequately integrate fire resilience and prevention.

This document establishes a consistent provincial approach for fuel management planning in British Columbia. The primary purpose of this document is to direct forest professionals in developing Wildfire Risk Reduction Plans, which strategically identify and prioritize areas for fuel management projects on Provincial Crown land adjacent to communities. The plan outlines a phased WRR Plan Development Process, moving from data collection and risk analysis to the delineation of planning units, such as Wildfire Risk Reduction Units, and the smallest operational-scale Fuel Management Units, with an emphasis on total-chance planning to ensure community resiliency by reducing wildfire intensity and increasing suppression opportunities. The successful execution of a WRR Plan requires extensive collaboration and coordination among various stakeholders, including the BC Wildfire Service, land managers, and Indigenous Nations.

This document outlines best management practices developed by the Chief Forester to reduce the harmful effects of slash pile burning in British Columbia forest management. The core purpose is to minimize waste, lower greenhouse gas emissions, and maximize fibre utilization through integrated planning, silviculture, and harvesting techniques. Rather than offering prescriptive solutions, the document presents a range of options, such as promoting partial cutting and scattering woody debris, which must be evaluated based on site-specific factors like fire risk, biodiversity, and economics. This document seeks to treat forest management as a versatile tool to achieve diverse environmental and resource values.

This document provides guidance on using fuel treatments and prescribed burning to protect whitebark pine forests, emphasizing methods to mitigate WBP mortality during fire. It outlines specific thresholds for crown and bark char damage that threaten tree survival and suggests that mechanical treatments may be necessary to reduce fuels prior to burning, particularly in areas with abundant competing conifers. The document categorizes forest stands as Good, Marginal, or Avoid Candidate Areas for prescribed burning based on the presence of cone-bearing WBP trees and vigorous regeneration, advocating for mechanical fuel reduction in high-value areas and generally advising against burning stands with high levels of cone-bearing trees or limited competition. Finally, the paper recommends coordinating fire planning with silviculturists and entomologists to account for factors like mountain pine beetle pressure and ensure a heterogeneous forest structure that minimizes the risk of large, high-severity wildfires.

This document details a study on the effect of commercial thinning on within-stand microclimate and fine fuel moisture in a mature lodgepole pine forest in southeastern British Columbia. Researchers compared thinned and unthinned stands, observing that thinning led to decreased rainfall interception and increases in solar radiation, wind speed, and near-surface air temperature. While fine fuel moisture content was lower in the thinned stand immediately after rain, these differences became very small under moderate and high fire danger conditions, suggesting minimal practical impact on ignition probability or crowning potential at those times. The study also validated the effectiveness of the Fine Fuel Moisture Code component of the Canadian Fire Weather Index System for predicting fuel moisture in both stand types during critical fire danger periods.

This document outlines a framework for restoring ponderosa pine and dry mixed-conifer forests on Colorado's Front Range, addressing the increased size and severity of recent wildfires. It emphasizes understanding the historical ecological dynamics of these forests, particularly changes in density and fire regimes, to inform modern management. The document details principles and guidelines for restoration and emphasizes the importance of spatial and temporal scale, enhancing desired and rare structural elements like openings and tree groups, and working with natural environmental gradients and disturbance patterns. This document provides a process for planning, implementing, and monitoring restoration projects, highlighting the crucial role of adaptive management and interdisciplinary collaboration to ensure forest resilience and sustained delivery of ecosystem services.

This webinar presents results from a simulation study of north-central New Mexico that investigated the relative effectiveness of a variety of fuel treatment strategies and the tradeoffs of implementing fuels programs with competing management goals.

This paper addresses the severe decline of High Elevation Five-Needle White Pine forests in western North America, primarily due to mountain pine beetle outbreaks, white pine blister rust, and altered fire regimes exacerbated by changing climates. The authors advocate for multi-scaled management interventions to promote resilience to disturbances and genetic resistance to white pine blister rust. The paper details the critical need for long-term programs like inventory, mapping, and research, alongside active restoration treatments such as mechanical cuttings and prescribed fires, and proactive tree-level measures like planting rust-resistant seedlings and protecting high-value trees, all while integrating climate change considerations throughout the planning and implementation process.

This research compiles and analyzes a national database of dead and down woody debris to improve fire behavior and effects modeling in Canadian forests. The study emphasizes that DWD is a major component of surface fuels, significantly impacting fire intensity, consumption, and the transition to crown fires. By examining various forest types and ecozones, the authors identified key predictive variables such as bioclimatic regime, age, and structural components. This work provides crucial tools for a more accurate understanding of DWD distribution across Canada, enhancing the country's ability to forecast and manage wildfires.

This paper investigates the factors influencing wildfire burn severity across Canada. Using statistical models applied to environmental data from 1981 to 2020, the authors identify fuel aridity as the most significant driver of how severely forests burn. Their analysis reveals that northern regions and summer months are particularly prone to high-severity fires, and they found a concerning trend of increasingly favorable conditions for severe burning in recent decades, particularly in spring and autumn. The study concludes that changing climates are making Canadian forests more susceptible to intense fires, highlighting the need for improved fire management and preparedness strategies.

This guidance document outlines best management practices for fuel treatment within British Columbia's Interior-Wet Fire Weather Zone, a region characterized by its productive forests and diverse tree species like western cedar and hemlock. While typically experiencing higher precipitation and less frequent stand-replacing wildfires, drier subzones are prone to mixed-severity fire regimes. The guide emphasizes managing surface fuels, ladder fuels that allow fire to climb, and crown fuels to reduce the intensity and spread of wildfires, especially given the increased risk from climate change-induced drought and successful fire suppression efforts near communities. The document aims to provide professional guidance for mitigating wildfire threats through strategic fuel management and maintaining forest health.

This document investigates how partial harvesting strategies, designed to enhance mule deer habitat and allow timber extraction in British Columbia's dry Douglas-fir forests, impact complex interactions with natural disturbances like insect outbreaks and wildfires. The study, spanning 30 years, found that while short-term harvesting altered forest structure and reduced the immediate risk of crown fires and Douglas-fir beetle infestations, many of these structural and susceptibility changes reverted over the long term. The removal of harvesting residuals proved more significant in mitigating long-term disturbance risks, particularly for Douglas-fir beetles and intense surface fires, than the time elapsed since the treatment itself. The authors conclude that sustainable forest management integrating timber extraction and mule deer habitat conservation is achievable if partial harvesting occurs at intervals of 30 years or less and residuals are promptly cleared.