8 resources found

This report outlines the Montane Alternative Silvicultural Systems study, a large-scale project designed to test the ecological and operational feasibility of harvest methods beyond conventional clearcutting in coastal British Columbia montane forests. The research examined the biological and silvicultural impacts of four systems, including clearcut, patch cuts, green tree retention, and shelterwood, to address concerns regarding regeneration, aesthetics, and biodiversity in challenging high-elevation environments. Key findings indicated that while clearcutting was often the most cost-effective, alternative systems faced specific issues, such as increased operational costs and shade limitations that suppressed seedling growth in the shelterwood treatments. The results offer actionable implications, suggesting that small patch cuts and low retention levels can be successfully implemented without significantly reducing early plantation performance.

This document summarizes the findings of the Montane Alternative Silvicultural Systems study, detailing a long-term comparison of how different harvesting techniques affect the survival and growth of western redcedar and yellow cedar. The study contrasted methods such as clearcut, shelterwood, and various retention systems over a 28-year period to assess key metrics like height and volume at the 25-year mark. The conclusions revealed that the silvicultural system profoundly impacts growth rates, showing that western redcedar grew fastest in clearcuts while yellow cedar achieved greater volume and height in the shaded shelterwood environments. This indicates distinct species preferences regarding light exposure following logging.

This presentation outlines the critical issue of ecological drought in British Columbia, distinguishing it from lack of precipitation by emphasizing the role of water deficit relative to average conditions and evapotranspiration. The core concern highlighted is how increasing temperatures due to climate change will intensify drought frequency and severity, despite potential precipitation increases, by reducing snowpacks and increasing water loss from the environment. The presentation explores recent drought occurrences, linking them to climate change and natural climate variability, and introduces a Forest Drought Risk Assessment Tool designed to evaluate and predict drought impacts on forests. The purpose of this presentation is to emphasize the urgent need to integrate climate change considerations into forestry practices to mitigate future ecological impacts.

This presentation focuses on the establishment and growth of aspen stands within the Sub-Boreal Spruce zone of British Columbia. It draws upon existing research to discuss key factors influencing aspen regeneration, including the importance of removing apical dominance through disturbances like logging or fire to promote suckering. The presentation also details harvest considerations, such as the benefits of winter harvesting and the negative impacts of excessive canopy retention and soil compaction. The presentation explores the effects of various silvicultural practices and the interactions between aspen and coniferous species like spruce and pine, providing guidance on site selection and stockingregeneration surveys for successful aspen management.

This document summarizes key findings from two long-term silvicultural research initiatives: the Montane Alternative Silvicultural Systems study and the Variable Retention Adaptive Management experiments. The MASS study, spanning 25 years, compared clearcutting to various alternative methods, revealing that tree growth was best in clearcuts, though other methods offered biodiversity benefits and paved the way for variable retention. The VRAM research explored different retention strategies, identifying windthrow as a significant challenge and demonstrating that retention provides crucial life-boating habitat for various species, with the amount, aggregation, and size of retained areas being critical factors. The research highlights that while increased canopy retention and dispersion can impact tree growth, these alternative systems offer important ecological advantages, particularly for understory vegetation and diverse species.

This document outlines the strategic approach to silvicultural systems in the Great Bear Rainforest, focusing on Ecosystem-Based Management. A central theme is the retention silvicultural system, which involves deliberately leaving trees and vegetation within harvested areas to maintain forest structure and biodiversity. The application of this system is context-dependent, influenced by the proportion of mature and old forest at both the broader landscape unit and immediate cutblock scales, with increased retention mandated where older forests are scarce. Additionally, the document addresses windthrow considerations at both landscape and stand levels, providing guidelines to mitigate damage while prioritizing the retention system in areas of lower wind hazard.

This document outlines the corporate and operational implementation of VR, including specific targets and zoning strategies, alongside a monitoring framework to ensure intended ecological outcomes are met. The document asserts that VR is crucial for future forest management as it aligns with broader BC initiatives for biodiversity and ecosystem health.

This presentation focuses on managing forests for resilience as a crucial method for achieving both forest sustainability and value. It begins by establishing the importance of resilience in the context of forestry, defining it across ecological, engineering, and social-ecological perspectives, and distinguishing between general and disturbance-specific resilience. The presentation then explores how to promote resilient forests, emphasizing the role of diversity, complexity, and understanding ecological systems. Through case studies and management principles, it demonstrates practical ways to enhance forest resilience at various spatial scales, acknowledging the inherent trade-offs in managing for future uncertainties like fire, insects, drought, and climate change.