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| Author | : David Paré |
| Publisher | : |
| Total Pages | : 16 |
| Release | : 1999 |
| Genre | : Soils |
| ISBN | : 9781552610480 |
| Author | : Alexandra Morley Hume |
| Publisher | : |
| Total Pages | : |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Understanding the impact of natural and anthropogenic disturbance on soil fertility and tree growth is critical to the sustainability of forest management, yet there remains much uncertainty regarding how both harvesting and wildfire affect soil nutrient dynamics, espe-cially over several decades and in varying overstory types. Historically, wildfire has been the dominant stand-replacing disturbance and an important mechanism of ecosystem renewal. However, intensive forest harvesting is replacing fire as the primary disturbance in many parts of the world, sparking concerns about nutrient depletion and decreased site productivity associated with biomass removals. I conducted a global meta-analysis of northern forest ecosystems to examine the ef-fects of forest harvesting on total concentrations and stoichiometric ratios of soil carbon ([C]), nitrogen ([N]), and phosphorus ([P]) relative to natural, uncut control stands, and whether these effects differed as a function of harvest intensity, soil depth, overstory type, and time since harvesting. I then used an age chronosequence from 7- to 33-years-old to ex-amine and compare the effects of clearcut harvesting and fire on soil nutrient concentrations and tree growth in three predominant upland boreal stand types (dominated by deciduous or coniferous trees, or a combination of both) during early stand development. The results of the meta-analysis indicated that harvesting negatively affects [C], [N], and [P] in the forest floor soil layer, but has positive or neutral effects on the mineral soils layer, except for when it is coupled with fire disturbance (through post-fire salvage logging or prescribed burn following harvest), which resulted in strong, negative effects on mineral soil [C] and [N]. The negative effect of harvesting on forest floor nutrients increased with harvesting intensity. Time since harvesting had a positive effect on soil [C] and [N], but less so for [P], which likely requires more time to recover given its reliance on inputs from min-eral weathering. Our chronosequence study also highlighted the important role of stand age (i.e. time since disturbance). Although fire resulted in more dramatic effects on soil nutrient concentra-tions and stand basal area than harvesting in the 7-year-old stands, these differences con-verged in the 15- and 33-year-old stands. Similar to the meta-analysis, the effects of disturb-ance were most profound in the forest floor layer, and temporal trends differed between bio-logically controlled nutrients (C and N), which recovered rapidly and linearly, and nutrients that are more geochemically controlled (P, K, and Ca). The results of both studies indicated that conifer stands are more sensitive to nutrient loss following disturbance than deciduous stands, and mixedwood stands are intermediate. Our findings highlight the importance of harvest intensity and rotation length on long-term soil nutrient health when managing northern forest ecosystems, particularly in conifer stands.
| Author | : Woongsoon Jang |
| Publisher | : |
| Total Pages | : 34 |
| Release | : 2015 |
| Genre | : Forest biomass |
| ISBN | : |
Biomass harvesting extracts an increased amount of organic matter from forest ecosystems over conventional harvesting. Since organic matter plays a critical role in forest productivity, concerns of potential negative long-term impacts of biomass harvesting on forest productivity (i.e., changing nutrient/water cycling, aggravating soil properties, and compaction) have emerged. There is abundant prediction of long-term impacts of intensive biomass removal on forest productivity. However, the empirical knowledge and comprehensive understanding, especially on western forests, are limited thus far. Therefore, we utilize the available findings to evaluate potential impacts of increased biomass extraction on western forests. We compare biomass harvesting with natural disturbance regimes or conventional harvesting systems in terms of organic matter redistribution in order to evaluate the possible consequences of biomass harvesting on forest productivity. We review the role of organic matter on forest productivity and compare the organic matter redistribution or removal through biomass harvesting and natural disturbances or conventional harvesting to assess potential impacts. The summarized findings are: (1) the long-term impacts of intensive biomass harvesting will be mitigated by protection of the belowground organic matter; (2) biomass harvesting could result in the accelerated leaching of nutrients; and (3) immediate understory vegetation recovery can minimize potential negative impacts. Finally, sites sensitive to harvesting impacts (e.g., fine-textured soil and steep slopes) should be approached with caution and prior planning to minimize undesirable responses.
| Author | : John M. Kimble |
| Publisher | : CRC Press |
| Total Pages | : 650 |
| Release | : 2002-09-25 |
| Genre | : Science |
| ISBN | : 1000738124 |
Much attention has been given to above ground biomass and its potential as a carbon sink, but in a mature forest ecosystem 40 to 60 percent of the stored carbon is below ground. As increasing numbers of forests are managed in a wide diversity of climates and soils, the importance of forest soils as a potential carbon sink grows. The Potenti
| Author | : D. W. Johnson |
| Publisher | : |
| Total Pages | : 32 |
| Release | : 1999 |
| Genre | : Forest soils |
| ISBN | : |
A report evaluating the long-term effects of harvesting on productivity, soil carbon, and nutrients within a variety of forest ecosystems.
| Author | : J. A. Nicolson |
| Publisher | : |
| Total Pages | : 19 |
| Release | : 1982* |
| Genre | : Cutover lands |
| ISBN | : |
| Author | : Jason James |
| Publisher | : |
| Total Pages | : 180 |
| Release | : 2018 |
| Genre | : |
| ISBN | : |
The properties and processes of deep soil horizons remain an important gap in knowledge due to the long history of shallow soil sampling. The majority of soil carbon and nitrogen can be found beneath the A horizon in most soils, particularly those deeper than one meter to bedrock. Such soils are common in many parts of the world, especially the Pacific Northwest where the combination of age (hundreds of thousands of years in many places) and high precipitation lead to rapid development of subsoil pedogenic features. My dissertation seeks to explore deep soils to better understand the relationships between nutrient cycles and the impact of land-use change and forest harvesting on soil carbon. In a series of 36 soil profiles sampled to 3 meters depth across the Pacific Northwest, pedogenesis frequently extended deeper than the upper 2 meters that is arbitrarily defined as the maximum soil depth for soil taxonomy. The combination of landslides, volcanic activity, and flooding have buried soils in many forests across the region, and these horizons can be important repositories of plant nutrients. In several cases, B horizon development extended deeper than could be excavated with a backhoe (3+ meters). The diversity of parent materials, climate gradients (with both latitude and orography), and soil carbon and nitrogen cycles directly control exchangeable cation cycling across the Pacific Northwest. Soils that experience more precipitation and contain higher levels of carbon and nitrogen hold less exchangeable calcium and magnesium in the whole soil profile, and also have more deeply distributed stocks of exchangeable cations within the profile. Consequently, human disturbances that alter soil carbon can have repercussions for plant nutrition. Millions of acres of forest in the US are actively managed for timber production, but the type and intensity of soil disturbance varies considerably. In a meta-analysis examining the response of soil carbon to forest management from 112 publications, I found that harvesting reduces soil carbon by 11% overall. This loss is predominately driven by O horizon losses (-30%), but there were also losses in surface mineral soil (0-15 cm; -3%). Loss of soil carbon extends deep into the soil with increasing average losses at each depth interval examined; however, very few studies examined soils deeper than 30 cm, leading to extremely wide confidence intervals in deeper soil. Land-use change, even converting one forest type for another, can substantially alter soil carbon cycling, as well. In the Brazilian Cerrado, over half of the natural vegetation has been lost to agriculture, silviculture or urban development, with a substantial portion of the landscape planted with Eucalyptus trees. The shift in the aboveground plant community increases aliphatic functional groups in water-soluble organic matter (WSOM), which may lead to reduced microbial biomass in Eucalyptus plantations that lack native understory trees. The difference in radiocarbon age between WSOM and bulk soil carbon is smaller under Eucalyptus relative to Cerrado, suggesting either mineralization or leaching of aged organic matter under this land use. The consequences of land-use change extend deep into the soil profile, particularly in the Oxisol soils of Brazil which are especially reliant upon soil organic matter for critical ecosystem services like nutrient recycling and water holding capacity.
| Author | : Aaron Brecka |
| Publisher | : |
| Total Pages | : |
| Release | : 2018 |
| Genre | : |
| ISBN | : |
The boreal forest is home to a thriving forest industry which requires stable, long term timber to remain viable. Anthropogenic climate change, caused by the release of greenhouse gasses, is occurring rapidly in northern locations. Climate change impacts the boreal forest in many different ways and has the potential impact forestry operations considerably. While there has been significant research on both climate change and the boreal forest, few studies combine both topics to include long-term timber supply. Knowledge gaps exist in terms of how ecological impacts from climate change will affect forestry, particularly in terms of net biomass, species compositions, forest disturbances and species migrations. There is also a lack of timber forecasting studies that utilize forest disturbances and implement drought mortality. Throughout this thesis, these key areas are addressed. We first conducted a literature review and synthesis of the impacts of climate change on boreal forest timber supply. We found that the disparity between migration rates of tree species with ongoing climate change may reduce the overall forest area of the boreal long term. Regional forest disturbances are increasing in frequency and intensity, affecting harvestable volumes and timber quality. Species compositions are changing; favoring early successional conifers and deciduous broadleaf species because of new local climates and more frequent disturbances. Most importantly, net biomass is likely in decline since regional increases in growth are outweighed by general increases in overall tree mortality. Our synthesis concluded that considerable reductions in the quality and quantity of boreal timber supply are likely to occur in the near future without forestry adaptation strategies or climate mitigation measures being implemented. We then simulated four climate change scenarios in three boreal forest regions to test the effect on long term timber supply and the success of two harvesting intensities. By adding annual, species specific, drought-induced tree mortality to a previously published landscape model, we sought to more completely study this important topic. Our results show long term declines in aboveground biomass, regional increases in tree mortality (from fires, insects and drought), and species composition shifts favoring broadleaf and temperate forest species. Our area-based harvesting prescriptions show that with lower harvesting intensity, consistent harvest levels area more likely to be maintained. However, our most severe climate forcing shows considerable reductions in aboveground biomass and harvested biomass. These findings necessitate action for mitigation of climate change and forestry adaptation strategies to cope with negative climate impacts. In summary, climate change considerably impacts the future success of boreal forestry. Our review of recent literature suggests that the consequences of climate change far outweigh the benefits. Our simulation results show annual biomass levels generally declines, especially in extreme future climates. Continued study and urgent management actions are needed to successfully adapt forest industry to the pressures of climate change.
| Author | : Martin F. Jurgensen |
| Publisher | : |
| Total Pages | : 398 |
| Release | : 1979 |
| Genre | : Ecology |
| ISBN | : |
Timber harvesting has a pronounced effect on the soil microflora by wood removal and changing properties. This paper gives a perspective on soil biology-harvesting relationships with emphasis on the northern Rocky Mountain region. Of special significance to forest management operations are the effects of soil micro-organisms on: the availability of soil nutrients, particularly nitrogen; the decay of woody plant material; and tree disease incidence. At present, no widespread detrimental impact on site quality in the northern Rocky Mountain region can be directly attributed to harvesting effects on the soil microflora.
