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1	Managing Slash to Minimize Colonization of Residual Leave Trees by Ips and Other Bark Beetle Species Following Thinning in Southwestern Ponderosa Pine DeGomez, Tom, Fettig, Christopher J., McMillin, Joel D., Anhold, John A., Hayes, Christopher 05 1900 (has links) 12 pp. / Pine Bark Beetles, THE PIÑON IPS BARK BEETLE, FIREWOOD AND BARK BEETLES IN THE SOUTHWEST, USING INSECTICIDES TO PREVENT BARK BEETLE ATTACKS ON CONIFERS, GUIDELINES FOR THINNING PONDEROSA PINE FOR IMPROVED FOREST HEALTH AND FIRE PREVENTION / Various techniques to reduce brood production of Ips and Dendroctonus spp. in ponderosa pine slash are discussed. stand density felling date green chaining solarization lop and scatter chipping semiochemical
2	Forest Canopies: Form and Functional Relationships Jack, Steven B. 01 May 1990 (has links) Forest canopy structure is strongly influenced by stand density due to changing competitive interactions among the individual trees and in turn directly influences stemwood volume production. The structure and dynamics of forest canopies, particularly in relation to the production of stemwood, were examined in unmanaged, even-aged stands of two dissimilar tree species, Pinus contorta var. latifolia Engelm. and Abies lasiocarpa (Hook.) Nutt. The analysis of structure-production relationships was guided by a conceptual model which generated hypotheses and led to examination of assumptions incorporated in the model. Mean crown dimensions were related to stand density through a negative exponential function for both species, but because of differing shade-tolerances, mean crown size of lodgepole pine was affected more by increasing density than was mean crown size of subalpine fir. More importantly, examination of the model assumptions indicated that adequate characterization of canopy structure should account for the influence of both crown shyness and stand height. Stand density also influenced the amount and distribution of leaf area in these forest stands. The more plastic mean leaf area of lodgepole pine led to a constant leaf area index over a range of density and, thus, was consistent with conventional wisdom which assumes closed canopied forest stands support stable leaf area indices across a wide range of densities. The less plastic mean leaf area of subalpine fir, however, led to positive correlation between leaf area index and density. Changes in mean crown dimensions and mean leaf area influenced the production of stemwood volume such that large mean crown sizes were less efficient than small mean crown sizes. The decrease in efficiency was attributed to accumulation of large branch biomass in large crowns to support foliage far from the stem. Increased support costs were indicated by the increasing proportion of crown volume which was nonfoliated as mean crown size increased. The assumption that accumulated branch biomass was responsible for the observed declines in efficiency for forest trees was reinforced by a comparison of structure-production relationships for lodgepole pine and the annual Helianthus annuus L. forest canopies stand density tree interaction stemwood Ecology and Evolutionary Biology Forest Sciences Plant Sciences
3	Thinning Effects on Forest Stands and Possible Improvement in a Stand Reconstruction Technique / 林分復元法における林分への間伐の影響、および補正の可能性 Heng, Sovanchandara 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第21807号 / 農博第2320号 / 新制\|\|農\|\|1065(附属図書館) / 学位論文\|\|H31\|\|N5179(農学部図書室) / 京都大学大学院農学研究科森林科学専攻 / (主査)教授大澤晃, 教授北島薫, 教授神﨑護 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Aboveground Biomass Total Stem Volume Stand Density Stump Information Stand Reconstruction Technique 610
4	Modeling maximum size-density relationships of loblolly pine (Pinus taeda L.) plantations VanderSchaaf, Curtis Lee 30 November 2006 (has links) Self-thinning quantifies the reduction in tree numbers due to density-dependent mortality. Maximum size-density relationships (MSDRs) are a component of self-thinning that describe the maximum tree density per unit area obtainable for a given average tree size, often quadratic mean diameter (D). An MSDR species boundary line has been defined as a static upper limit of maximum tree density -- D relationships that applies to all stands of a certain species within a particular geographical area. MSDR dynamic thinning lines have been defined as the maximum tree density obtainable within an individual stand for a particular D which have been shown to vary relative to planting density. Results from this study show that differences in boundary levels of individual stands cause the MSDR species boundary line slope estimate to be sensitive to the range of planting densities within the model fitting dataset. Thus, a second MSDR species boundary line was defined whose slope is the average slope of all MSDR dynamic thinning lines. Mixed-models are presented as a statistical method to obtain an estimate of the population average MSDR dynamic thinning line slope. A common problem when modeling self-thinning is to determine what observations are within generally accepted stages of stand development. Segmented regression is presented as a statistical and less subjective method to determine what observations are within various stages of stand development. Estimates of D and trees per acre (N) where MSDR dynamic thinning lines begin and end on the logarithmic scale were used as response variables and predicted as a function of planting density. Predictions of MSDR dynamic thinning line beginning and ending D and N are used in an alternative MSDR dynamic thinning line slope estimation method. These models show that the maximum value of Reineke's Stand Density Index (SDI) varies relative to planting density. By relating planting density specific Zone of Imminent Competition Mortality boundaries to a MSDR species boundary line, self-thinning was found not to begin at a constant relative SDI. Thus, planting density specific Density Management Diagrams (DMD) showed that self-thinning began at 40 to 72% for planting densities of 605 and 2722 seedlings per acre, respectively. / Ph. D. size-density trajectories stand density index density management diagrams self-thinning mixed models
5	An Adaptive Computer Vision Technique for Estimating the Biomass and Density of Loblolly Pine Plantations using Digital Orthophotography and LiDAR Imagery Bortolot, Zachary Jared 06 May 2004 (has links) Forests have been proposed as a means of reducing atmospheric carbon dioxide levels due to their ability to store carbon as biomass. To quantify the amount of atmospheric carbon sequestered by forests, biomass and density estimates are often needed. This study develops, implements, and tests an individual tree-based algorithm for obtaining forest density and biomass using orthophotographs and small footprint LiDAR imagery. It was designed to work with a range of forests and image types without modification, which is accomplished by using generic properties of trees found in many types of images. Multiple parameters are employed to determine how these generic properties are used. To set these parameters, training data is used in conjunction with an optimization algorithm (a modified Nelder-Mead simplex algorithm or a genetic algorithm). The training data consist of small images in which density and biomass are known. A first test of this technique was performed using 25 circular plots (radius = 15 m) placed in young pine plantations in central Virginia, together with false color othophotograph (spatial resolution = 0.5 m) or small footprint LiDAR (interpolated to 0.5 m) imagery. The highest density prediction accuracies (r2 up to 0.88, RMSE as low as 83 trees / ha) were found for runs where photointerpreted densities were used for training and testing. For tests run using density measurements made on the ground, accuracies were consistency higher for orthophotograph-based results than for LiDAR-based results, and were higher for trees with DBH ≥10cm than for trees with DBH ≥7 cm. Biomass estimates obtained by the algorithm using LiDAR imagery had a lower RMSE (as low as 15.6 t / ha) than most comparable studies. The correlations between the actual and predicted values (r2 up to 0.64) were lower than comparable studies, but were generally highly significant (p ≤ 0.05 or 0.01). In all runs there was no obvious relationship between accuracy and the amount of training data used, but the algorithm was sensitive to which training and testing data were selected. Methods were evaluated for combining predictions made using different parameter sets obtained after training using identical data. It was found that averaging the predictions produced improved results. After training using density estimates from the human photointerpreter, 89% of the trees located by the algorithm corresponded to trees found by the human photointerpreter. A comparison of the two optimization techniques found them to be comparable in speed and effectiveness. / Ph. D. stand density LiDAR loblolly pine plantations biomass aerial photograph Optimization genetic algorithm computer vision Nelder-Mead simplex
6	Efecto de la densidad de plantación y la frecuencia de corte en el rendimiento y valor nutritivo de Morus multicaulis, de un año establecimiento Rojas Torkar, Carolina Paz January 2005 (has links) No description available. Agronomía
7	DENSIDADE DE ÁRVORES POR DIÂMETRO NA FLORESTA ESTACIONAL DECIDUAL NO RIO DO GRANDE SUL / DENSITY OF TREES BY DIAMETER IN SEASONAL DECIDUOUS FOREST IN RIO GRANDEDO SUL Meyer, Evandro Alcir 28 February 2011 (has links) Conselho Nacional de Desenvolvimento Científico e Tecnológico / The objective of the work was to study the relationship between the density of trees per hectare and the average diameter to a Deciduous Forest, as well as adjust the model to describe this behavior Reineke. The study area is located in the town of Silveira Martins, in the central region of Rio Grande do Sul and is in early stages of succession after agriculture. The information about the number of the trees per hectare and the average diameter were obtained by the method of density-off proposed by Spurr. These plots were sampled in the early stages of a secondary forest, picking up areas where the predominant Camboatá-vermelho (Cupania vernalis). As natural forests have irregular spacing, density is highly variable, therefore, to select only high-density plots were chosen in areas that there was the occurrence of dead individuals. Were tested different methods to estimate the upper limit of the self thinning line: regression analysis (for all data and relative density greater than 60%), correcting the intercept so that the wastes were negative, the manual adjustment, the relative density (DR> 90%) and stochastic frontier analysis. The method that estimated the maximum density was regression analysis with data from at least 60% of maximum density, obtaining a slope of -1.563 for the model of Reineke. There was no significant difference between the powers provided by the different methods. The maximum Stand Density Index was 1779 trees per hectare, to a dg of 25 cm. The density management diagram was constructed on the basis of basal area, number of trees per hectare and diameter of the tree of average basal area. Were used the densities of 15% and 60%, to close the canopy, and the induction of mortality, respectively. The densities were determined proportionally to the maximum density by stand density index (PDI) for a reference diameter of 25 cm in different classes of index 200, since the IDP 1700, to a minimum of 300. Populations whose density is greater than 60% of the maximum were considered overstocked, between 60 and 15% fully stocked, and below 15% under stocked. They recommended a combination of Dendrogram generated in this study with the method of Spurr to guide interventions in the Deciduous Forest. / O objetivo deste trabalho foi estudar a relação entre a densidade de árvores por hectare e o diâmetro médio para uma Floresta Estacional Decidual, bem como, ajustar o modelo Reineke para descrever este comportamento. A área de estudo localiza-se no município de Silveira Martins, na região central do Rio Grande do Sul e encontra-se em estágio inicial de sucessão, após uso agrícola. As informações referentes ao número de árvores por hectare e o diâmetro médio foram obtidas por meio do método de densidade pontual proposto por Spurr. Estas parcelas foram amostradas nos estágios iniciais de uma floresta secundária, escolhendo-se áreas onde predominava o camboatá-vermelho (Cupania vernalis). Como as florestas naturais apresentam espaçamento irregular, a densidade é bastante variável, assim sendo, para selecionar apenas parcelas em alta densidade, foram escolhidas áreas em que se verificava a ocorrência de indivíduos mortos. Foram testados diferentes métodos para estimar o limite superior da linha de autodesbaste: a análise de regressão (para todos os dados e densidade relativa maior que 60%), corrigindo o intercepto para que os resíduos fossem negativos; o ajuste manual; o de densidade relativa (DR>90%) e a análise de fronteira estocástica. O método que melhor estimou a máxima densidade foi a análise de regressão com dados de no mínimo 60% da densidade máxima, obtendo um coeficiente angular de -1,563 para o modelo de Reineke. Não houve diferença significativa entre as potências fornecidas pelos diferentes métodos. O Índice de Densidade de Povoamento máximo foi de 1779 árvores por hectare, para o dg de 25 cm. O diagrama de manejo da densidade foi construído em função da área basal, do número de árvores por hectare e do diâmetro da árvore de área basal média. Foram utilizadas as densidades de 15% e 60%, para o fechamento das copas, e a indução da mortalidade, respectivamente. Os níveis de densidade foram determinados, proporcionalmente, à máxima densidade por índice de densidade do povoamento (IDP), para um diâmetro de referência de 25 cm, em classes de índice de 200, desde o IDP de 1700, até o mínimo de 300. Populações cuja densidade for maior que 60% da máxima foram consideradas superestocadas, entre 60 e 15% estocadas, e abaixo de 15% subestocadas. Recomendou-se a combinação do Dendrograma gerado neste estudo com o método de Spurr para guiar as intervenções na Floresta Estacional Decidual. Autodesbaste Densidade pontual Competição Índice de densidade de povoamento Diagrama de manejo da densidade Self-thinning Point density Competition Stand density index Density management diagram
8	Financial Feasibility of Increasing Carbon Sequestration in Mississippi Forests Sector Nepal, Prakash 30 April 2011 (has links) The specific objectives of this project were: 1) Determine financial viability of enrolling forest landowners in Chicago Climate Exchange (CCX) forestry carbon offset protocols; 2) Determine financial trade-offs associated with managing loblolly pine (Pinus taeda L.) and Cherrybark oak (Quercus pagoda Raf.) stands for increased carbon sequestration and timber; 3) Examine financial feasibility of increasing carbon accumulation in wood products carbon by extending rotation length of loblolly pine stands; and 4) Explore potential impacts of carbon policies and programs on future carbon accumulation in Mississippi’s forest sector. Rotation age Net Present Value Loblolly pine Cherrybark Oak Compensation Chicagho Climate Exchage Carbon Policy Carbon Credits Aforestation Stand Density Index
9	Growth and Site Conditions of Acacia mangium, Acacia hybrid, Eucalyptus urophylla, Cinnamomum parthenoxylon and Erythropholeum fordii for Livelihood Security of Smallholders in Industrial Tree Planting Programs of Vietnam Sein, Chaw 16 February 2012 (has links) No description available. 500 Naturwissenschaften Forest Sciences and Forest Ecology Durchmesser Höhe Volumen Bestandesdichte Site-Index Grundfläche Diameter Height Volume Stand density Site Index Basal Area Landarbeitslehre
10	立木密度の違うコジイ幼齢林の構造と物質生産只木, 良也, TADAKI, Yoshiya 12 1900 (has links) (PDF) 農林水産研究情報センターで作成したPDFファイルを使用している。立木密度コジイ幼齢林純生産量密度効果自然枯死 stand density Castanopsis cuspidata net production density effect natural thinning

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