213 resources found

This document addresses the challenge of balancing timber harvesting with the conservation of at-risk plant communities that depend on mature and old forest conditions in British Columbia's Coastal Douglas Fir biogeoclimatic zone. Recognizing the scarcity of these older forests, the document outlines silvicultural practices aimed at maintaining existing structural diversity in high-conservation areas and accelerating the development of old-growth characteristics in younger, more homogenous stands. Ultimately, it seeks to equip forest professionals with strategies to enhance the ecological functions of older forests within provincial forest lands.

This paper synthesizes the disparate groundwater responses to wildfire, noting that post-fire effects range from significant increases to decreases in water fluxes like recharge and baseflow. The authors evaluate this variability across five primary categories: climate, vegetation, hydrogeology, fire characteristics, and the cryosphere, focusing on both short-term and intermediate recovery periods. A critical finding is that post-wildfire responses often align with hydroclimatic settings where water input and evaporative demand are out of sync, while the pre-wildfire groundwater regime significantly influences the expected outcome and recovery trajectory. This paper provides a collection of testable hypotheses and identifies key areas, particularly the influence of snow dynamics and cryospheric processes, for future monitoring and modeling efforts to improve the prediction of groundwater recovery after fires.

The Good Fire Podcast explores the concept of fire as a tool for ecological health, cultural empowerment, and Indigenous stewardship. The term good fire refers to intentional, controlled burns used by Indigenous communities to maintain healthy landscapes and cultural traditions.

This webinar examines how legal objectives for mule deer winter range and old growth management affect the Stswecem'c Xget'tem First Nation's ability to reduce wildfire risk, adapt to climate change, and restore ecocultural values in their south-central BC forests. Despite the impacts of settler-colonial policies, SXFN has long stewarded their territory using fire. In partnership with the University of British Columbia, they assessed crown fire risk, fuel loads, and potential treatments, highlighting both current stewardship efforts and the importance of Indigenous sovereignty in land management.

This document introduces the Mitigating Wildfire Initiative, an effort to address catastrophic wildfires in British Columbia through dialogue and collaboration among diverse groups, including Indigenous Peoples and local communities. The MWI has four key objectives: strengthening relationships, improving understanding of wildfire issues, creating a shared agenda for mitigation, and achieving real-world impact. The document delves into the complex concept of resilience in the context of wildfire, differentiating between ecological, social, and social-ecological perspectives, and emphasizes the importance of place-based and context-specific discussions for effective strategies. Finally, it outlines five interconnected categories of progress being made toward wildfire resilience in BC including planning, operations, networking, research and knowledge generation, and public engagement, highlighting the need for an all-of-society approach and proactive, dynamic management.

This paper investigates how wildfires influence the upward migration of tree species in California's subalpine forests, a phenomenon often linked to climate change. Researchers examined post-fire tree regeneration across various fire severities, focusing on the contrasting responses of shade-tolerant and shade-intolerant conifer species. While overall montane species regeneration decreased in burned areas, shade-intolerant Jeffrey pine showed increased success in severely burned plots, aligning with predictions of higher climatic suitability. Conversely, shade-tolerant red fir regeneration declined significantly with higher fire severity, suggesting that the specific regeneration niche of a species, its ideal post-fire conditions, is critical in determining whether fire facilitates or hinders its range expansion.

This extension note explores the critical role of fire in the dry interior forests of British Columbia, which historically experienced frequent, low-intensity surface fires that maintained ecosystem health and biodiversity. The authors explain how human fire exclusion over the past 60 years has dramatically altered these forests, leading to increased fuel loads, higher tree density, altered species composition, and a greater risk of intense, large-scale crown fires. The documen then outlines four management options for these sites: continued fire suppression, controlled prescribed burns, mechanical fuel reduction, or a combination of these strategies, emphasizing the need to balance ecological, social, and economic considerations. Finally, the document highlights various ongoing research initiatives aimed at understanding fire regimes and developing integrated management solutions for these fire-adapted ecosystems.

This document outlines best management practices for fuel treatment within British Columbia's interior-dry fire weather zone, a region characterized by dry ecosystems like Interior douglas fir, ponderosa pine, and bunchgrass zones. It emphasizes how wildfires significantly influence these forest ecosystems, historically maintaining biodiversity and grasslands through low-intensity burns. The guide details fuel management strategies for surface, ladder, and crown fuels, including thinning, pruning, and species conversion, all aimed at reducing the risk and intensity of high-severity wildfires. Additionally, it provides recommendations for mitigating impacts on forest health from treatments and includes case studies illustrating effective fuel management practices.

This document outlines best management practices for fuel treatment in the Boreal Fire Weather Zone, characterized by the Boreal White and Black Spruce BEC zone. This document emphasizes that this zone experiences large, intense wildfires often started by lightning, which significantly impact forest succession. The text details how fire suppression has increased flammable older forests, making communities more vulnerable, and classifies the predominant fuel types according to the Canadian Forest Fire Behaviour Prediction System. Finally, it provides comprehensive recommendations for fuel management, including surface, ladder, and crown fuel reduction, along with strategies for maintenance and mitigating impacts on forest health, all aimed at reducing wildfire risk.

This document outlines best management practices for fuel treatment within British Columbia's coastal fire weather zone, encompassing the Coastal Western Hemlock and Coastal Douglas Fir biogeoclimatic zones. It details the ecology of this temperate rainforest, noting that while mature stands typically resist widespread fires due to high moisture and closed canopies, disturbed areas and specific drier zones are more prone to fire, especially with the presence of invasive species. The core purpose is to guide fire management through specific interventions, focusing on surface, ladder, and crown fuel reduction to prevent canopy fires, alongside recommendations for forest health mitigation to prevent pest outbreaks after treatment. The document also references established Canadian Forest Fire Behaviour Prediction System fuel types to characterize fire risk and includes practical examples of post-treatment characteristics from various locations.

This document from the BC Wildfire Service provides comprehensive guidance for developing Fuel Management Prescriptions, specifically for projects aimed at wildfire risk reduction funded by various government programs. It outlines the purpose and core principles of effective fuel management, emphasizing the need for specific and measurable targets for fire behavior reduction and site-specific considerations tied to WRR objectives. The document details the required sections and content for a FMP template, covering everything from project identification and descriptions of fuel treatment units to intricate details about soil characteristics, legal and non-statutory considerations, and precise fuel loading and treatment specifications. This document aims to equip qualified professionals with the necessary framework to design treatments that reduce fire intensity, support suppression efforts, and balance wildfire mitigation with other ecological and social values.

This technical report introduces Landscape Fire Management as a crucial, integrated approach to addressing escalating wildfire risks while restoring ecosystem health. LFM is presented as a paradigm shift, moving beyond localized efforts to encompass broader landscapes by coordinating various land management activities and setting complementary wildland fire objectives across different land-use zones. The document outlines six core principles for effective LFM practice: defining the landscape, understanding current and future conditions, assessing risks to values, setting cohesive objectives, coordinating interventions, and continuously learning through adaptive management. This report aims to guide diverse land managers in British Columbia towards a more resilient coexistence with fire by detailing strategies like fuel breaks, fire-tolerant stands, and managing fuel loads.

This report outlines the Lower North Thompson Community Forest Wildfire Risk Management Plan, a comprehensive strategy developed to address the increasing threat of wildfires in British Columbia. Initiated in 2018, the plan identifies and evaluates wildfire risks, considering factors like ignition probability, fire intensity, and values at risk such as human life, infrastructure, and environmental assets. It proposes five key management strategies including wildfire management zones, silviculture, strategic harvesting, prescribed fire, and collaborative planning aimed at enhancing wildfire resilience and mitigating negative impacts, while also exploring potential ecological opportunities associated with fire. The plan emphasizes a proactive and adaptive approach, recommending annual progress reports and a five-year renewal cycle to adjust to changing conditions.

This document outlines best management practices for fuel treatment within British Columbia's Interior-Subalpine Fire Weather Zone, a high-elevation region dominated by coniferous forests like Engelmann Spruce-Subalpine Fir and Montane Spruce zones. It details the ecology of this fire zone, highlighting how fires historically occur less frequently but with high severity, often leading to stand-replacing events that favor species like lodgepole pine. The document also explains how these areas are classified within the Canadian Forest Fire Behaviour Prediction system for fuel types, providing specific guidelines for managing surface, ladder, and crown fuels to reduce wildfire risk. Finally, this document offers recommendations for mitigating impacts on forest health, including strategies to prevent pest outbreaks and maintain stand resilience after fuel treatments.

This document outlines Best Management Practices for fuel treatment within British Columbia's Central Plateau Fire Weather Zone, a region historically shaped by frequent, stand-destroying wildfires. It details the zone's diverse ecosystems and vegetation, highlighting how species like lodgepole pine thrive in fire-prone areas, while others like Douglas-fir develop fire-resistant bark. The guide also classifies common fuel types using the Canadian Forest Fire Behaviour Prediction system, emphasizing management strategies for surface, ladder, and crown fuels, including techniques like thinning and encouraging deciduous species to reduce wildfire risk. Finally, it provides examples of past fuel management projects and discusses considerations for forest health, such as preventing pest outbreaks and maintaining stand integrity.

This manual outlines the comprehensive process for implementing commercial thinning operations in British Columbia, driven by the need to address fiber shortages caused by natural disturbances. The document is structured to guide various users, from forest planners selecting appropriate stands and assessing economic viability, to field supervisors and machine operators executing the thinning process. It details crucial stages including identifying suitable stands based on specific criteria like species and age, meticulous planning at the block level encompassing pre-harvest assessment and selecting optimal harvesting systems, and the practical implementation with an emphasis on coaching operators and diligent monitoring. The manual also highlights the importance of post-harvest assessment and considers broader implications, such as the long-term impact on timber supply and the integration of non-timber values like wildlife habitat and wildfire risk reduction.

This document serves as a comprehensive manual for forest professionals, outlining best practices for thinning operations effective April 2025. Its primary purpose is to support sustainable forest management by providing science-based guidelines for developing and implementing thinning prescriptions, particularly for enhancing timber production and quality. The guidance emphasizes maintaining ecological and social objectives while focusing on operational efficiency, minimizing environmental impacts, and promoting innovative approaches. It also details the required data collection and monitoring processes to ensure the effectiveness and compliance of thinning activities, thereby fostering healthy, resilient forest ecosystems across British Columbia.

This extension note introduces Equivalent Clearcut Area, a metric used to assess the potential impact of forest disturbances, like logging or fires, on watershed hydrology in snow-dominated regions of British Columbia. The document explains how ECA is calculated by accounting for the area disturbed and the subsequent forest regrowth, which influences water interception, evaporation, and transpiration. It details the historical development and application of ECA in forest management planning, highlighting its use as an indicator for potential changes in streamflow and peak flow events. While acknowledging ECA's utility as a simplified tool for risk assessment and comparing management options, the note also stresses its limitations, emphasizing that it should not be used as a stand-alone metric due to the complex and variable nature of watershed responses to disturbance.

This document introduces revised estimates for snow recovery in pine-dominated forests of British Columbia's interior, a critical factor for watershed management. Snow recovery refers to the restoration of snow accumulation and melt patterns in regrowing forests after clearcutting, compared to mature forests and clearcut areas. The authors highlight how changes in forest cover significantly impact spring streamflow peaks, making accurate recovery estimates essential for assessing potential hydrologic changes. The study presents new recovery curves based on long-term data from the Thompson-Okanagan region, demonstrating that previous estimates likely overstated the rate of snow recovery, suggesting a more gradual return to pre-harvest conditions as young forests grow taller.

This paper presents the 8-year results of a silvicultural systems trial at Lucille Mountain in British Columbia's Engelmann Spruce-Subalpine Fir zone. The study investigates the effects of different logging methods like clearcutting, patch cutting, and various partial cuts on climate, regeneration, tree growth, wind damage, arboreal lichens, and litter decomposition. The research highlights the complex environmental responses to forest harvesting in this high-elevation ecosystem and provides initial insights for better managing these sensitive forests, including considerations for reforestation practices and the challenges of adaptive management.