Factores anatómicos, dendrométricos y climáticos implicados en la producción de resina de Pinus pinaster AIT. : aplicación a la mejora de los métodos de resinación

Pinus pinaster Ait. es la conífera con mayor área de distribución en la Península Ibérica y es, a día de hoy, la única especie resinada en nuestro país. La inducción del flujo de resina al exterior para su recolección a través de distintos tipos de heridas ha sido practicada desde hace miles de años por distintas culturas. En todos los casos, las técnicas desarrolladas se basan en la estimulación del característico sistema de defensa de las pináceas. En los últimos siete años se viene observando una tendencia de incremento sustancial de la superficie resinada en España, acompañada por avances tecnológicos dirigidos a la mecanización y mejora de estimulantes. El aprovechamiento resinero se perfila como un sector estratégico en la generación de empleo rural y la conservación de ecosistemas. La industria resinera demanda métodos de extracción más eficaces, una selvicultura adecuada y actualizada, y condiciones laborales de los resineros más dignas con objeto de llegar a ser competitiva en el mercado internacional. Este trabajo se centra en ampliar el conocimiento sobre el sistema de defensa de P. pinaster, concretamente sobre las estructuras y procesos que pueden afectar a la producción de resina. Se analizan las relaciones entre las características anatómicas del xilema, destacando las relacionadas con los canales resiníferos, las variables dendrométricas y dasométricas de la masa y el flujo de resina (objetivo 1). Se estudia cómo estas relaciones son moduladas por las heridas de resinación dependiendo de la técnica de resinación aplicada (objetivo 2), el clima y el balance hídrico del suelo (objetivo 3). El material vegetal, las muestras de suelo y los datos de producción de resina y climáticos usados en esta tesis han sido recogidos en tres montes de utilidad pública; MUP 101 en Armuña, MUP 108 en Melque de Cercos y MUP 117 en Nieva (en esta última solo se recogieron los datos de producciones), todos ellos pinares monoespecíficos de P. pinaster localizados en la denominada Tierra de Pinares Segoviana. En los árboles de nuestro estudio se han aplicado cuatro métodos de resinación: método de pica de corteza con estimulante y método mecanizado con estimulante, ambos en sentido ascendente y descendente. En los trabajos realizados para el análisis de la influencia de la anatomía constitutiva en la producción de resina (objetivo 1) y el efecto del clima (objetivo 3), se obtuvieron muestras del xilema de 26 árboles resinados en Melque de Cercos y Armuña y 12 árboles control sin resinar. Para caracterizar los pies estudiados, se midió la altura, diámetro normal y porcentaje de copa viva. Las muestras de tejido fueron recogidas en una zona del tronco a una distancia del límite de la herida considerada en la bibliografía como no afectada (anatomía constitutiva). Para el análisis de las alteraciones anatómicas inducidas por la herida (objetivo 2), se recogieron muestras en ocho de los individuos en los que se habían realizado los distintos métodos de resinación descritos y en cinco árboles control. Se obtuvieron ocho muestras de tejido distribuidas en la parte superior, inferior, lateral y centro de la herida de cada uno de los árboles resinados. Para establecer las diferencias en la producción de resina según el método de resinación, se analizaron las producciones de 561 árboles resinados en 2012 con estos cuatro métodos en Nieva. Los principales resultados de estos trabajos muestran que la producción de resina está ligada al volumen de canales (axiales y radiales) y a la frecuencia de canales radiales existentes en el árbol antes de efectuar ninguna herida (sistema constitutivo). De esta manera, los árboles grandes productores de resina mostraron una red de canales más densa que aquellos con producciones medias. Una vez realizada la herida de resinación, observamos una disminución del ancho del anillo de crecimiento y del tamaño medio de los canales axiales a la vez que se incrementaba la frecuencia y área ocupada por mm2 de anillo de estos canales. Estos cambios perduraron en el árbol durante al menos tres años y fueron distintos dependiendo de la localización en el entorno de la herida y del método de resinación. Las respuestas más intensas a la herida se observaron el año siguiente a la realización de la misma, en dirección axial, para las distancias más próximas al límite de la herida y para los métodos de resinación en sentido ascendente. Además, se ha constatado que como consecuencia de las heridas de resinación se produjeron cambios en la anatomía del xilema en zonas alejadas de la herida, tanto en el año de la herida como años posteriores. Es decir, se observó una respuesta sistémica del árbol. Respecto al papel del clima como regulador de la respuesta del árbol, se ha evidenciado que la temperatura, la radiación y la ETP influyeron en la producción de resina, no solo durante la campaña de resinación, sino también durante los meses anteriores. El déficit hídrico favoreció la producción y la formación de canales axiales pero, a partir de un determinado umbral, esa relación se invirtió y las lluvias estivales incrementaron la producción. Algunas de estas variables climáticas se asociaron a cambios en el tamaño y frecuencia de las estructuras secretoras, las cuales posiblemente modulan la respuesta defensiva de la planta. La dendrometría del árbol (evaluada a través del diámetro normal, altura y porcentaje de copa viva), la densidad de la masa y el tipo de suelo influyeron en el potencial de producción de resina de P. pinaster. Árboles más vigorosos, parcelas con menores densidades y suelos con más capacidad para la retención de agua y nutrientes presentaron producciones mayores. Estos trabajos se complementan en anexos con una caracterización del sistema socio-ecológico del pinar en resinación. En ese trabajo se identifican sus potenciales servicios ecosistémicos y se evalúa su grado de vinculación con el aprovechamiento resinero con objeto de valorar su funcionalidad y aproximar una valoración económica de modo que sea posible apreciar la importancia económica de los mismos. Para concluir, podemos resaltar que son necesarios más trabajos de carácter científico para avanzar en la comprensión de los procesos anatómicos y fisiológicos que regulan la secreción de resina en P. pinaster y sus interacciones con el medio. Esto permitiría avances certeros hacia el desarrollo de métodos de extracción más eficaces, una selvicultura óptima, el reconocimiento de los beneficios socio-ecológicos y económicos del aprovechamiento y, de manera general, una bibliografía amplia y fiable para la consulta y desarrollo de futuras mejoras que posibiliten la reactivación y conservación de la resinación como aprovechamiento rentable. ABSTRACT Pinus pinaster Ait. is the most widespread conifer in Spain and is now the only species tapped for its oleoresin. External induction of resin secretion, based on the defense system of Pinus trees, has been performed by humans since Classical times through various methods. The socio-economic implication of this practice in Spain justifies a new approach to improve tapping methodology and understand the effects of this activity on the tree. In the last five years, sharp increases in the price of natural resins, accompanied by technological advances directed toward mechanization, have made resin tapping a strategic activity for rural development and forest conservation. The resin industry demands more efficient tapping methods and forest management plans as a way to increase competitiveness in a global market. In this way, this work focuses on the study of the defense system of P. pinaster, with the aim to understand the effects of anatomical and physiological characteristics and environmental conditions on resin yield. The relationships between anatomical variables -with special focus on resin canals-, dendrometric and dasometric variables, and resin yield will be evaluated (objective 1). The tapping wound effects (objective 2) and the intra- and inter-annual variability of climate conditions and soil water availability influence (objective 3) on resin yield will be also studied. The plant and soil material and the resin yield and climatic data used in this thesis have been collected in stands of three public forests of P. pinaster; Armuña, Melque de Cercos and Nieva, located in Segovia (Central Spain). Trees were tapped using two different methods: mechanized or traditional tool, in both upwards and downwards direction. Twenty-six tapped trees of contrasting resin yield classes and twelve non-tapped (control) trees, growing in two locations (Armuña y Melque de Cercos) with the same climate but different stand density and soil characteristics, were selected for studying the role of tree size, xylem anatomy at distal parts aside from the tapping wound (objective 1) and climate influence (objective 3) on resin yield. Concerning the tree defenses induced by the tapping wound (objective 2), the xylem of eight trees, tapped with the two described methods in both upwards and downwards direction, were analyzed. From each tapped tree, eight cores were collected at different locations and varying distances from the tapping wound. In each core, a histological analysis was made. Growth ring width, earlywood and latewood width, and axial canal frequency, area, mean size and location were measured. The effect of the tapping method on resin yield was assessed in 561 P. pinaster tapped trees in a stand in Nieva. In tissues not affected by the tapping wound, the frequency of radial resin canals and the total volume of resin canals were related to resin yield. The frequency of radial canals and the resin yield were strongly related to tree diameter and percentage of live crown. High area of axial resin canals per mm2 was related to high yielding trees, but only in the location with higher plant density and poorer soil quality. In tapped trees, an increase in axial canal frequency and area was found during the three years following the start of tapping activity, suggesting that canal formation is a systemic induced response to wounding. The highest mean annual resin yield was found using the traditional tool in upwards direction, which also induced the highest increase in axial canal frequency and area. The lowest yield was found for mechanized tapping, which showed no differences between the upwards and downwards directions. The strongest induction of systemic induced responses in terms of resin canal frequency and area was detected one year after tapping for upwards tapping. This suggests the involvement of signaling processes that spread mainly upwards, and the importance of adaptive processes as a defense against periodic insect attacks. Intra-annual variation in resin yield was strongly correlated with temperature, solar radiation, potential evapotranspiration and soil water deficit. Inter-annual variation in resin yield and resin canal abundance were correlated with temperature and water deficit in spring, but above a certain threshold of cumulated water deficit in summer rainfall favored resin yield. Under adverse climate scenarios where resource optimization is desirable, a reduced tapping season during the warmest months (June–September) would be advisable, assuming a very small production loss relative to traditional tapping season. Similarly, in years with a rainy summer and/or dry spring, a slightly longer tapping season could be suggested, as resin yield increases after these events. Tree diameter and percentage of live crown, and radial resin canal frequency could be useful criteria for estimating resin yields in P. pinaster. Vigorous trees in lower density stands and growing up in good quality soils will be the most productive. These conclusions could be applied to improve tapping management and breeding programs. These works are complemented with socio-ecological characterization, the identification of the main ecosystem services and an assessment of the possible economic impact derived from the tapping practice. To conclude, more scientific studies are necessary for understanding the anatomical and physiological processes behind resin synthesis and their interactions with the environment. This would afford further progresses towards an extensive and reliable bibliography and improved tapping methods and optimal selvicultural guide lines.

The interspecific mass–density relationship and plant geometry

We present an a priori theoretical framework for the interspecific allometric relationship between stand mass and plant population density. Our model predicts a slope of −\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \setlength{\oddsidemargin}{-69pt} \begin{document} \begin{equation*}\frac{1}{3}\end{equation*}\end{document} between the logarithm of stand mass and the logarithm of stand density, thus conflicting with a previously assumed slope of −½. Our model rests on a heuristic separation of resource-limited living mass and structural mass in the plant body. We point out that because of similar resource requirements among plants of different sizes, a nonzero plant mass–density slope is primarily defined by structural mass. Specifically, the slope is a result of (i) the physical size-dependent relationship between stem width and height, (ii) foliage-dependent demands of conductance, and (iii) the cumulative nature of structural mass. The data support our model, both when the potential sampling bias of taxonomic relatedness is accounted for and when it is not. Independent contrasts analyses show that observed relationships among variables are not significantly different from the assumptions made to build the model or from its a priori predictions. We note that the dependence of the plant mass–density slope on the functions of structural mass provides a cause for the difference from the zero slope found in the animal population mass–density relationship; for the most part, animals do not have a comparable cumulative tissue type.

Using Florida Keys Reference Sites As a Standard for Restoration of Forest Structure in Everglades Tree Islands

In south Florida, tropical hardwood forests (hammocks) occur in Everglades tree islands and as more extensive forests in coastal settings in the nearby Florida Keys. Keys hammocks have been less disturbed by humans, and many qualify as “old-growth,” while Everglades hammocks have received much heavier use. With improvement of tree island condition an important element in Everglades restoration efforts, we examined stand structure in 23 Keys hammocks and 69 Everglades tree islands. Based on Stand Density Index and tree diameter distributions, many Everglades hammocks were characterized by low stocking and under-representation in the smaller size classes. In contrast, most Keys forests had the dense canopies and open understories usually associated with old-growth hardwood hammocks. Subject to the same caveats that apply to off-site references elsewhere, structural information from mature Keys hammocks can be helpful in planning and implementing forest restoration in Everglades tree islands. In many of these islands, such restoration might involve supplementing tree stocking by planting native trees to produce more complete site utilization and a more open understory.

Improved models for estimating temporal changes in carbon sequestration in above-ground biomass of mixed-species environmental plantings

Plantings of mixed native species (termed 'environmental plantings') are increasingly being established for carbon sequestration whilst providing additional environmental benefits such as biodiversity and water quality. In Australia, they are currently one of the most common forms of reforestation. Investment in establishing and maintaining such plantings relies on having a cost-effective modelling approach to providing unbiased estimates of biomass production and carbon sequestration rates. In Australia, the Full Carbon Accounting Model (FullCAM) is used for both national greenhouse gas accounting and project-scale sequestration activities. Prior to undertaking the work presented here, the FullCAM tree growth curve was not calibrated specifically for environmental plantings and generally under-estimated their biomass. Here we collected and analysed above-ground biomass data from 605 mixed-species environmental plantings, and tested the effects of several planting characteristics on growth rates. Plantings were then categorised based on significant differences in growth rates. Growth of plantings differed between temperate and tropical regions. Tropical plantings were relatively uniform in terms of planting methods and their growth was largely related to stand age, consistent with the un-calibrated growth curve. However, in temperate regions where plantings were more variable, key factors influencing growth were planting width, stand density and species-mix (proportion of individuals that were trees). These categories provided the basis for FullCAM calibration. Although the overall model efficiency was only 39-46%, there was nonetheless no significant bias when the model was applied to the various planting categories. Thus, modelled estimates of biomass accumulation will be reliable on average, but estimates at any particular location will be uncertain, with either under- or over-prediction possible. When compared with the un-calibrated yield curves, predictions using the new calibrations show that early growth is likely to be more rapid and total above-ground biomass may be higher for many plantings at maturity. This study has considerably improved understanding of the patterns of growth in different types of environmental plantings, and in modelling biomass accumulation in young (<25. years old) plantings. However, significant challenges remain to understand longer-term stand dynamics, particularly with temporal changes in stand density and species composition. © 2014.

Cartographie récente et écologie du nerprun bourdaine en Estrie

Le nerprun bourdaine (Rhamnus frangula L.) est une espèce exotique qui envahit plusieurs régions du sud du Québec, et plus particulièrement la région administrative de l'Estrie. Actuellement, on connaît encore peu l'écologie de l'espèce dans le contexte québécois et il n’existe pas de portrait d’ensemble de sa distribution dans les forêts tempérées de cette région. Dans ce contexte, le premier objectif du projet était de cartographier par télédétection la distribution du nerprun bourdaine dans deux secteurs de l'Estrie. Un second objectif était d'évaluer les variables environnementales déterminantes pour expliquer le recouvrement de nerprun bourdaine. La phénologie du nerprun bourdaine diffère de celle de la plupart des espèces indigènes arborescentes puisque ses feuilles tombent plus tard en automne. Cette caractéristique a permis de cartographier, par démixage spectral, la probabilité d'occurrence du nerprun bourdaine grâce à une série temporelle d'images du capteur OLI de Landsat 8. Le recouvrement du nerprun bourdaine a été calculé dans 119 placettes sur le terrain. La cartographie résultante a montré un accord de 69% avec les données terrain. Une image SPOT-7, dont la résolution spatiale est plus fine, a ensuite été utilisée, mais n’a pas permis d'améliorer la cartographie, puisque la date d’acquisition de l’image n’était pas optimale dû à un manque de disponibilité. Concernant le second objectif de la recherche, la variable la plus significative pour expliquer la présence de nerprun bourdaine était la densité du peuplement, ce qui suggère que l’ouverture de la couverture forestière pourrait favoriser l’envahissement. Néanmoins, les résultats tendent à démontrer que le nerprun bourdaine est une espèce «généraliste» qui s’adapte bien à plusieurs conditions environnementales.

Cartographie récente et écologie du nerprun bourdaine en Estrie

Le nerprun bourdaine (Rhamnus frangula L.) est une espèce exotique qui envahit plusieurs régions du sud du Québec, et plus particulièrement la région administrative de l'Estrie. Actuellement, on connaît encore peu l'écologie de l'espèce dans le contexte québécois et il n’existe pas de portrait d’ensemble de sa distribution dans les forêts tempérées de cette région. Dans ce contexte, le premier objectif du projet était de cartographier par télédétection la distribution du nerprun bourdaine dans deux secteurs de l'Estrie. Un second objectif était d'évaluer les variables environnementales déterminantes pour expliquer le recouvrement de nerprun bourdaine. La phénologie du nerprun bourdaine diffère de celle de la plupart des espèces indigènes arborescentes puisque ses feuilles tombent plus tard en automne. Cette caractéristique a permis de cartographier, par démixage spectral, la probabilité d'occurrence du nerprun bourdaine grâce à une série temporelle d'images du capteur OLI de Landsat 8. Le recouvrement du nerprun bourdaine a été calculé dans 119 placettes sur le terrain. La cartographie résultante a montré un accord de 69% avec les données terrain. Une image SPOT-7, dont la résolution spatiale est plus fine, a ensuite été utilisée, mais n’a pas permis d'améliorer la cartographie, puisque la date d’acquisition de l’image n’était pas optimale dû à un manque de disponibilité. Concernant le second objectif de la recherche, la variable la plus significative pour expliquer la présence de nerprun bourdaine était la densité du peuplement, ce qui suggère que l’ouverture de la couverture forestière pourrait favoriser l’envahissement. Néanmoins, les résultats tendent à démontrer que le nerprun bourdaine est une espèce «généraliste» qui s’adapte bien à plusieurs conditions environnementales.

Wood density : a tool to find complementary species for the design of mixed species plantations

The successful establishment and growth of mixed-species forest plantations requires that complementary or facilitatory species be identified. This can be difficult in many tropical areas because the growth characteristics of endemic species are often unknown, particularly when grown at potentially higher densities in plantations than in natural forests. Here, we investigate whether wood density is a useful and readily accessible trait for choosing complementary species for mixed species plantations. Wood density represents the carbon investment per unit volume of stem with a trade-off generally found between fast (low wood density) and slow (high wood density) growing species. To do this, we use data collected from 18 highly diverse mixed species plantations (4–23 mostly native species) aged from 6 to 11 years at the time of data collection located on Leyte Island, Philippines. We found significant negative correlations between wood densities and the height of the most abundant species, as well as with measures of overall stand growth and tree diameter size distribution. Not only do species with denser woods have slower growth rates, but also mixed-species plantations with higher average wood density and higher stem density were also less productive, at least in these young plantations. Similarly, stands with a high diversity in wood densities were less productive. There is growing interest in making greater use of native multi-species mixtures in smallholder and community planting programs in the tropics, and our results show databases of wood density values may help improve their design. In the early development stages of plantations, canopy closure and rapid height growth are usually key silvicultural targets, and wood density values can predict the rapid height development of species. If plantations are being grown for the livelihood of small landholders then the best target is to choose some species with different wood densities. This allows an early harvest of low-wood density species for early income, and will also reduce competition for slower growing trees with higher wood densities for later income generation.

Comparative study of lead-acid batteries for photovoltaic stand-alone lighting systems

The lead-acid battery is often the weakest link in photovoltaic (PV) installations. Accordingly, various versions of lead-acid batteries, namely flooded, gelled, absorbent glass-mat and hybrid, have been assembled and performance tested for a PV stand-alone lighting system. The study suggests the hybrid VRLA batteries, which exhibit both the high power density of absorbent glass-mat design and the improved thermal properties of the gel design, to be appropriate for such an application. Among the VRLA-type batteries studied here water loss for the hybrid VRLA batteries is minimal and charge-acceptance during the service at high temperatures is better in relation to their AGM counterparts.

Characterization of Linear Low-Density Polyethylene/ Poly(vinyl alcohol) Blends and Their Biodegradability by Vibrio sp. Isolated from Marine Benthic Environment

Increasing amounts of plastic waste in the environment have become a problem of gigantic proportions. The case of linear low-density polyethylene (LLDPE) is especially significant as it is widely used for packaging and other applications. This synthetic polymer is normally not biodegradable until it is degraded into low molecular mass fragments that can be assimilated by microorganisms. Blends of nonbiodegradable polymers and biodegradable commercial polymers such as poly (vinyl alcohol) (PVA) can facilitate a reduction in the volume of plastic waste when they undergo partial degradation. Further, the remaining fragments stand a greater chance of undergoing biodegradation in a much shorter span of time. In this investigation, LLDPE was blended with different proportions of PVA (5–30%) in a torque rheometer. Mechanical, thermal, and biodegradation studies were carried out on the blends. The biodegradability of LLDPE/PVA blends has been studied in two environments: (1) in a culture medium containing Vibrio sp. and (2) soil environment, both over a period of 15 weeks. Blends exposed to culture medium degraded more than that exposed to soil environment. Changes in various properties of LLDPE/PVA blends before and after degradation were monitored using Fourier transform infrared spectroscopy, a differential scanning calorimeter (DSC) for crystallinity, and scanning electron microscope (SEM) for surface morphology among other things. Percentage crystallinity decreased as the PVA content increased and biodegradation resulted in an increase of crystallinity in LLDPE/PVA blends. The results prove that partial biodegradation of the blends has occurred holding promise for an eventual biodegradable product

Short-term effects of manipulated increase in acid deposition on soil, soil solution chemistry and fine roots in Scots pine (Pinus sylvestris) stand on a podzol

A manipulated increase in acid deposition (15 kg S ha(-1)), carried out for three months in a mature Scots pine (Pinus sylvestris) stand on a podzol, acidified the soil and raised dissolved Al at concentrations above the critical level of 5 mg l(-1) previously determined in a controlled experiment with Scots pine seedlings. The induced soil acidification reduced tree fine root density and biomass significantly in the top 15 cm of soil in the field. The results suggested that the reduction in fine root growth was a response not simply to high Al in solution but to the depletion of exchangeable Ca and Mg in the organic layer, K deficiency, the increase in NH4:NO3 ratio in solution and the high proton input to the soil by the acid manipulation. The results from this study could not justify the hypothesis of Al-induced root damage under field conditions, at least not in the short term. However, the study suggests that a short exposure to soil acidity may affect the fine root growth of mature Scots pine.

Biometria e qualidade fisiológica de sementes de diferentes matrizes de Tabebuia chrysotricha (Mart. Ex A. DC.) Stand I.

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Combining adapted Judo training and pharmacological treatment to improve bone mineral density on postmenopausal women: A two years study

Background & Study Aim: Physical activity has been an important factor to increase bone mineral density (BMD) and, consequently, to prevent and treat osteoporosis. The study aimed the effects of adapted Judo training on BMD in postmenopausal women, during pharmacological treatment. Material & Methods: Eighteen female volunteers participated in this study. They were separated into two groups: Adapted Judo training (AJT) (n=11; 52.2±5.3 years) and control group (CG) (n=7; 53.8±4.4 years). Lunar GE Dual Energy X-Ray Absorptiometry (DXA) measured BMD at lumbar L2-L4, femoral neck and trochanter sites. The training period for AJT was two years, comprised 12 mesocycles with different intensities. ANOVA compared 2 groups in 3 moments of testing and Scheffé Test allowed multiple comparisons between groups for the L2-L4 and femoral neck sites, but at trochanter was Fisher LSD. Results: ANOVA showed significant differences in the AJT group (F(2, 32)=15.187, p=0.000023). Scheffé Test showed significant increase on lumbar BMD after one year of AJT (Δ%=+8.9%, p=0.000017) and after two years this improvement stand still (p=0.33). The CG after one year presented significant decrease in BMD of femoral neck (Δ%=-6.9%, p=0.03) and trochanter (Δ%=-3.7%, p=0.0084). However, the CG recovered the loss of BMD of femoral neck (Δ%=+7.6%, p=0.02) and trochanter (Δ%=+3.8%, p=0.0079) after two years of study. Conclusions: Drug therapy, without the physical activity practice, can aid the maintenance of BMD. AJT may be considered as an efficient physical activity for postmenopausal women with low BMD in pharmacological treatment. © ARCHIVES OF BUDO | SCIENCE OF MARTIAL ARTS.

Stand scale variability of topsoil organic matter composition in a high-elevation Norway spruce forest ecosystem

Our knowledge about the effect of single-tree influence areas on the physicochemical properties of the underlying mineral soil in forest ecosystems is still limited. This restricts our ability to adequately estimate future changes in soil functioning due to forest management practices. We studied the stand scale spatial variation of different soil organic matter species investigated by 13C NMR spectroscopy, lignin phenol and neutral sugar analysis under an unmanaged mountainous high-elevation Norway spruce (Picea abies L.) forest in central Europe. Multivariate geostatistical approaches were applied to relate the spatial patterns of the different soil organic matter species to topographic parameters, bulk density, oxalate- and dithionite-extractable iron, pH, and the impact of tree distribution. Soil samples were taken from the mineral top soil. Generally, the stand scale distribution patterns of different soil organic matter compounds could be divided into two groups: Those compounds, which were significantly spatially correlated with topography/altitude and those with small scale spatial pattern (range ≤ 10 m) that was closely related to tree distribution. The concentration of plant-derived soil organic matter components, such as lignin, at a given sampling point was significantly spatially related to the distance of the nearest tree (p ≤ 0.05). In contrast, the spatial distribution of mainly microbial-derived compounds (e.g. galactose and mannose) could be attributed to the dominating impact of small-scale topography and the contribution of poorly crystalline iron oxides that were significantly larger in the central depression of the study site compared to crest and slope positions. Our results demonstrate that topographic parameters dominate the distribution of overall topsoil organic carbon (OC) stocks at temperate high-elevation forest ecosystems, particularly in sloped terrain. However, trees superimpose topography-controlled OC biogeochemistry beneath their crown by releasing litter and changing soil conditions in comparison to open areas. This may lead to distinct zones with different mechanisms of soil organic matter degradation and also stabilization in forest stands.

The Effects of Density, Spatial Pattern, and Competitive Symmetry on Size Variation in Simulated Plant Populations

Patterns of size inequality in crowded plant populations are often taken to be indicative of the degree of size asymmetry of competition, but recent research suggests that some of the patterns attributed to size‐asymmetric competition could be due to spatial structure. To investigate the theoretical relationships between plant density, spatial pattern, and competitive size asymmetry in determining size variation in crowded plant populations, we developed a spatially explicit, individual‐based plant competition model based on overlapping zones of influence. The zone of influence of each plant is modeled as a circle, growing in two dimensions, and is allometrically related to plant biomass. The area of the circle represents resources potentially available to the plant, and plants compete for resources in areas in which they overlap. The size asymmetry of competition is reflected in the rules for dividing up the overlapping areas. Theoretical plant populations were grown in random and in perfectly uniform spatial patterns at four densities under size‐asymmetric and size‐symmetric competition. Both spatial pattern and size asymmetry contributed to size variation, but their relative importance varied greatly over density and over time. Early in stand development, spatial pattern was more important than the symmetry of competition in determining the degree of size variation within the population, but after plants grew and competition intensified, the size asymmetry of competition became a much more important source of size variation. Size variability was slightly higher at higher densities when competition was symmetric and plants were distributed nonuniformly in space. In a uniform spatial pattern, size variation increased with density only when competition was size asymmetric. Our results suggest that when competition is size asymmetric and intense, it will be more important in generating size variation than is local variation in density. Our results and the available data are consistent with the hypothesis that high levels of size inequality commonly observed within crowded plant populations are largely due to size‐asymmetric competition, not to variation in local density.

Effects of Strand Geometry on Selected Properties of Long-Stand Structural Composite Lumber Made from Northeastern Hardwoods

Structural composite lumber (SCL) products often possess significantly higher design values than the top grades of solid lumber, making it a popular choice for both residential and commercial applications. The enhanced mechanical properties of SCL are mainly due to defect randomization and densification of the wood fiber, both largely functions of the size, shape and composition (species) of the wood element. Traditionally, SCL manufacturers have used thin, rectangular elements produced from either moderate density softwoods or low density hardwoods. Higher density hardwood species have been avoided, as they require higher pressures to adequately densify and consolidate the wood furnish. These higher pressures can lead to increased manufacturing costs, damage to the wood fiber and/or a product that is too dense, making it heavy and unreceptive to common mechanical fastening techniques. In the northeastern United States high density, diffuse-porous hardwoods (such as maple, beech and birch) are abundant. Use of these species as primary furnish for a SCL product may allow for a competitive advantage in terms of resource cost against products that rely on veneer grade logs. Proximity to this abundant and relatively inexpensive resource may facilitate entry of SCL production facilities in the northeastern United States, where currently none exist. However, modifications to current strand sizes, geometries or production techniques will likely be required to allow for use of these species. A new SCL product concept has been invented allowing for use of these high density hardwoods. The product, referred to as long-strand structural composite lumber (LSSCL), uses strands of significantly larger cross sectional areas and volumes than existing SCL products. In spite of the large strand size, satisfactory consolidation is achieved without excessive densification of the wood fiber through use of a symmetrical strand geometric cross-section. LSSCL density is similar to that of existing SCL products, but is due mainly to the inherent density of the species, rather than through densification. An experiment was designed and conducted producing LSSCL from both large (7/16”) and small (1/4”) strands, of both square and triangular geometric cross sections. Testing results indicate that the large, triangular strands produce LSSCL beams with projected design values of: Modulus of elasticity (MOEapp) – 1,750,000 psi; Allowable bending stress (Fb) – 2750 psi; Allowable shear stress (Fv) – 260 psi. Several modifications are recommended which may lead to improvement of these values, likely allowing for competition against existing SCL products.