8 resources found

This paper investigates the practicality of current wildfire fuel reduction goals in north-central British Columbia by examining mechanical raking treatments within the Burns Lake Community Forest. The study assessed if these treatments achieved the targeted fuel load of 1-5 tonnes per hectare in areas deemed high risk for wildfire. Their findings suggest that meeting these targets using current methods is challenging and potentially unsustainable, highlighting the need for a standardized fuel measurement methodology and more adaptable fuel load targets that consider ecological and operational factors. The research advocates for a more feasible and scientifically sound approach to wildfire risk reduction in the region, emphasizing the importance of consistent data collection for future comparisons and improved practices.

This extension note details a case study on patch cutting in old-growth forests in British Columbia. The primary purpose of this research was to investigate alternative silviculture systems, specifically patch cutting, as a method to maintain caribou habitat. The study aimed to assess the impact of this harvesting technique on the abundance and dispersal of arboreal lichen, a critical food source for caribou, while also considering its effects on windthrow and other forest health factors.

This paper investigates the effectiveness of various fuel treatments in mitigating wildfire behavior in British Columbia's seasonally dry forests, a region increasingly vulnerable to extreme fires. Through field measurements and fire behavior modeling, the study assessed how different combinations of thinning, pruning, and residue fuel management impact the potential for crown fires and tree mortality. Key findings suggest that high-intensity thinning is more effective at reducing both passive and active crown fire potential and tree mortality compared to low-intensity thinning, while pruning after thinning offered little additional benefit. The study also highlights that chipping or pile burning residue fuel can reduce crown fire risk, but cautions that chipping may lead to delayed tree mortality not captured by current models, indicating a need for further research on its long-term effects.

This paper examines how community forests in British Columbia, Canada, are transforming wildfire governance by shifting away from traditional, centralized, and reactive approaches toward proactive, locally-driven management. The authors highlight that CFs, which are long-term forest tenures managed by Indigenous and/or local communities, act as local leaders in mitigating wildfire risk. Their success hinges on crucial factors such as financial and social capacity, particularly the ability to build trust and strong relationships with both community members and government agencies. Despite persistent challenges, the study concludes that CFs are a critical form of local wildfire governance, effectively implementing diverse strategies and fostering a fire lens in forest management to enhance wildfire resilience across various scales.

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 paper investigates how different forest harvesting methods impact both the amount of carbon stored and the variety of plant and tree life. The study compared the effects of clearcutting, varying levels of partial tree retention, and no harvesting across different climatic regions in British Columbia's Douglas-fir forests, ranging from humid to semi-arid. The central finding is that the intensity of harvesting significantly influences carbon storage and biodiversity, but importantly, the magnitude of these effects is strongly linked to the regional climate.

This paper explores the future of carbon storage within these vital ecosystems of British Columbia. Using a computer model, the researchers investigated how interactions between tree species, fire, forest management, and a changing climate might affect the ability of these forests to absorb and store carbon until 2050. A key aspect of their work was the introduction of a new metric, net sector productivity, which offers a more comprehensive way to account for carbon by including not only forest ecosystems but also harvested wood products. The study aimed to provide a better understanding for developing effective climate change mitigation and adaptive management strategies in these forests.

This report details an initiative undertaken to understand and address the impacts of climate change on ecosystems and forest management in the West Kootenay region of British Columbia. The project aimed to assess ecological vulnerability using local climate projections, collaboratively learn with forest practitioners and scientists, and case study relevant concepts like vulnerability, resilience, and risk management. The report outlines the methodologies employed - including climate modeling and bioclimate envelope analysis - and the findings regarding projected climate changes, potential impacts on ecosystems, and an initial assessment of ecosystem vulnerability across different subregions. The report serves as a foundation for identifying potential adaptation options for forest management and discusses barriers, incentives, and opportunities for implementing these changes in the face of a changing climate.