Global ETD Search

21	Aboveground and belowground response of European beech to drought: field studies and experiments / Ober- und unterirdische Reaktion der Rotbuche auf Trockenheit: Freilandstudien and Experimente Meier, Ina Christin 03 May 2007 (has links) No description available. 580 Pflanzen (Botanik) WNA 250 WNO 000 Mathematics and Natural Science Altbäume Blattgröße Blattstreckung Bodenfeuchte common garden-Experiment δ<sup>13</sup>C-Gehalt Fagus sylvatica Feinwurzelbiomasse Feinwurzellebensdauer Feinwurzelproduktion genetische Variabilität LAI Minirhizotrone Niederschlagsgradient Optimalitätstheorie phänotypische Plastizität Rotbuche Trockenheit Wurzellabor Wurzelmorphologie adult trees common garden experiment δ<sup>13</sup>C-signature Fagus sylvatica fine root biomass fine root longevity fine root production fine root turnover genetic variability LAI leaf expansion leaf size mini-rhizotrons optimal partitioning theory phenotypic plasticity precipitation gradient rhizolab root morphology soil moisture 42.91
22	Intra- and interspecific variation of functional traits, growth performance and belowground competition in <i>Populus</i> species Hajek, Peter 27 March 2014 (has links) No description available. 333 577 Populus tremula Populus tremuloides Fine root morphology Genetic variation Intraspecific variation Relative growth rate Root tissue density Specific root area Asymmetric competition Pioneer roots Root age Fine root morphology Root order Genetic variability Vulnerability to cavitation P50 Hydraulic conductivity High conductivity roots Coarse root anatomy Branch xylem anatomy Vessel diameter Relative growth rate Poplar Ökologie {Biologie} (PPN619463619)
23	Distribution spatiale des racines fines, disponibilité de la lumière et rendement dans un système de culture intercalaire avec arbres feuillus en zone tempérée Bouttier, Léa 04 1900 (has links) Les distributions spatiales des racines fines de Quercus rubra L. (CHR), Populus deltoides x nigra (DN3570) (PEH) et d’une culture fourragère (FOUR) ont été étudiées dans un système agroforestier de culture intercalaire (SCI) du sud du Québec (Canada). L’étude ne révèle pas d’enracinement plus profond des arbres en SCI, mais des profils superficiels à l’instar de nombreuses espèces d’arbres en plantations ou en milieu naturel. Une séparation spatiale existe entre les systèmes racinaires du FOUR et des CHR dont la densité relative selon la profondeur est plus faible que celle de la culture de 0 à 10 cm, mais plus élevée de 10 à 30 cm. Les PEH ne présentent pas d’adaptation racinaire et les hautes valeurs de densités de longueur racinaires (FRLD) de surface près du tronc entraînent une diminution de 45 % de la densité racinaire de surface du fourrage, suggérant une forte compétition pour les ressources du sol. L’étude du rendement agricole a d’ailleurs révélé des réductions de biomasse fourragère particulièrement près des PEH. Cependant, les résultats d’une analyse à composantes principales suggèrent un impact secondaire de la compétition racinaire sur le rendement agricole, et une plus grande importance de la compétition pour la lumière. L’impact des PEH à croissance rapide sur la culture est plus grand que celui du CHR. Cependant, ils seront récoltés plus rapidement et l’espace libéré favorisera la croissance de la culture intercalaire. Cet aspect dynamique des SCI les rapproche des écosystèmes naturels et devrait être réfléchi et approfondi pour leur succès futur. / Spatial distributions of fine roots were studied in a tree-based intercrop system (TBI) with Quercus rubra L. (CHR), Populus deltoides x nigra (DN3570) (PEH) and pasture species (FOUR) in southern Québec (Canada). Results didn’t show deeper root profiles for trees in TBI. Profiles were superficial as commonly found for tree species grown in conventional plantations or in natural ecosystems. More than 95 % of fine roots were found in 25 cm and 45 cm depth for CHR and PEH, and in 35 cm for pasture. However, spatial separation exists between CHR and pasture fine roots systems as CHR allocate less fine roots in the top 10 cm of soil, and more between 10 cm et 30 cm. PEH fine roots didn’t show any adaption when intercropped with pasture and a high value fine root length density (FRLD) in top soil layer near tree trunk reduces pasture FRLD by 45 %, suggesting strong competition interaction for resources. Pasture yield analysis revealed biomass reduction near trees, particularly near PEH. However results of a principal component analysis indicates stronger negative effect of light reduction on pasture yield than the presence of tree fines roots. PEH, a fast growing species, have stronger impact than CHR on pasture yield but they will be harvested sooner and larger alleys should benefit the intercrop. This dynamic aspect of TBI systems is close to natural ecosystems and should be further investigated for future success. Système de culture intercalaire Densité de racine fines Distribution spatiale Réduction de lumière séparation spatiale Compétition rendements Tree based intercrop systems fine root lenght density spatial distribution light reduction spatial separation competition yields
24	Effects of tree species composition on fine root biomass and dynamics in the rhizosphere of deciduous tree stands in the Hainich National Park (Thuringia) / Effects of tree species composition on fine root biomass and dynamics in the rhizosphere of deciduous tree stands in the Hainich National Park (Thuringia) Jacob, Andreas 21 November 2012 (has links) No description available. 570 Acer pseudoplatanus belowground complementarity Carpinus betulus Fagus sylvatica Fraxinus excelsior fine root biomass old-growth forest root competition Tilia cordata belowground overyielding ingrowth cores mixed stands monospecific stands root longevity ammonium glycine nitrate root uptake 15N trace Biologie (PPN619462639)
25	Biomass production and nutrient cycling in short-rotation coppice willow (Salix spp.) bioenergy plantations in Saskatchewan, Canada 2013 December 1900 (has links) Biomass energy is currently the largest renewable contributor to global energy supply and there is increasing demand for bioenergy feedstock. Consequently, the production of purpose-grown woody bioenergy crops, such as short rotation coppice (SRC) willow, is expected to proliferate. Although the economic and environmental benefits associated with SRC willow production are well documented, systematic assessments of nutrient cycling within these plantations are rare. The objective of this study was to examine biomass production and biogeochemical cycling of nitrogen (N), phosphorus (P), potassium (K), sulphur (S), calcium (Ca), and magnesium (Mg) during an initial four-year rotation of six willow varieties grown at four plantations along a 500 km north-south pedoclimatic gradient within Saskatchewan, Canada. Nutrient budgets were also calculated after quantifying various nutrient inputs (e.g., atmospheric deposition, soil mineral weathering, and organic matter mineralization), outputs (e.g., above- and below-ground biomass, leaching, and denitrification), and transfers (e.g., canopy exchange, leaf litter decomposition, and fine root turnover) affecting the plant available soil nutrient pool. Total stem, leaf litter, and below-ground (primarily fine roots) biomass production after four years averaged 19.0, 7.1, and 12.5 Mg ha-1, respectively, with corresponding soil nutrient budget deficits of 17, 39, 112, 271, and 74 kg ha-1 of N, P, K, Ca, and Mg, respectively, but a soil S surplus of 60 kg ha-1. Despite willow’s relatively low nutrient-demanding nature, negligible leaching and denitrification losses, and substantial nutrient cycling from leaf litter, the nutrient export in harvested biomass over multiple rotations will require soil nutrient amendments, particularly N and P, to maintain plantation productivity. Given the apparent eventual need for supplemental fertility to support adequate willow growth over the 22-yr plantation life span, the fate of broadcast 15N-labelled fertilizer was also examined. Though the willow accumulated less than ⅓ of the applied fertilizer N after one year, the majority of the residual fertilizer N (51%) remained available for willow uptake in subsequent years. Further research is needed to track the fate of applied fertilizers over multiple rotations to better understand fertilizer dynamics for optimizing SRC willow agronomy; thus helping to promote its viability as a biomass energy feedstock option. Chernozem decomposition limit value decomposition rate constant canopy exchange dry deposition fine root turnover leaching leaf litter decomposition mineral weathering nutrient budgets 15N-labelled fertilizer principal component analysis Vertisol
26	Distribution spatiale des racines fines, disponibilité de la lumière et rendement dans un système de culture intercalaire avec arbres feuillus en zone tempérée Bouttier, Léa 04 1900 (has links) Les distributions spatiales des racines fines de Quercus rubra L. (CHR), Populus deltoides x nigra (DN3570) (PEH) et d’une culture fourragère (FOUR) ont été étudiées dans un système agroforestier de culture intercalaire (SCI) du sud du Québec (Canada). L’étude ne révèle pas d’enracinement plus profond des arbres en SCI, mais des profils superficiels à l’instar de nombreuses espèces d’arbres en plantations ou en milieu naturel. Une séparation spatiale existe entre les systèmes racinaires du FOUR et des CHR dont la densité relative selon la profondeur est plus faible que celle de la culture de 0 à 10 cm, mais plus élevée de 10 à 30 cm. Les PEH ne présentent pas d’adaptation racinaire et les hautes valeurs de densités de longueur racinaires (FRLD) de surface près du tronc entraînent une diminution de 45 % de la densité racinaire de surface du fourrage, suggérant une forte compétition pour les ressources du sol. L’étude du rendement agricole a d’ailleurs révélé des réductions de biomasse fourragère particulièrement près des PEH. Cependant, les résultats d’une analyse à composantes principales suggèrent un impact secondaire de la compétition racinaire sur le rendement agricole, et une plus grande importance de la compétition pour la lumière. L’impact des PEH à croissance rapide sur la culture est plus grand que celui du CHR. Cependant, ils seront récoltés plus rapidement et l’espace libéré favorisera la croissance de la culture intercalaire. Cet aspect dynamique des SCI les rapproche des écosystèmes naturels et devrait être réfléchi et approfondi pour leur succès futur. / Spatial distributions of fine roots were studied in a tree-based intercrop system (TBI) with Quercus rubra L. (CHR), Populus deltoides x nigra (DN3570) (PEH) and pasture species (FOUR) in southern Québec (Canada). Results didn’t show deeper root profiles for trees in TBI. Profiles were superficial as commonly found for tree species grown in conventional plantations or in natural ecosystems. More than 95 % of fine roots were found in 25 cm and 45 cm depth for CHR and PEH, and in 35 cm for pasture. However, spatial separation exists between CHR and pasture fine roots systems as CHR allocate less fine roots in the top 10 cm of soil, and more between 10 cm et 30 cm. PEH fine roots didn’t show any adaption when intercropped with pasture and a high value fine root length density (FRLD) in top soil layer near tree trunk reduces pasture FRLD by 45 %, suggesting strong competition interaction for resources. Pasture yield analysis revealed biomass reduction near trees, particularly near PEH. However results of a principal component analysis indicates stronger negative effect of light reduction on pasture yield than the presence of tree fines roots. PEH, a fast growing species, have stronger impact than CHR on pasture yield but they will be harvested sooner and larger alleys should benefit the intercrop. This dynamic aspect of TBI systems is close to natural ecosystems and should be further investigated for future success. Système de culture intercalaire Densité de racine fines Distribution spatiale Réduction de lumière séparation spatiale Compétition rendements Tree based intercrop systems fine root lenght density spatial distribution light reduction spatial separation competition yields
27	Furnitura multipla di servizi ecosistemici da culture energetiche poliennali / MULTIPLE ECOSYSTEM SERVICES PROVISION FROM PERENNIAL BIOENERGY CROPS / Multiple ecosystem services provision from perennial bioenergy crops FERRARINI, ANDREA 17 March 2016 (has links) La sfida nel 21esimo secolo è quella di fornire cibo e energia ad un mondo in continua crescita demografica e allo stesso tempo conservare l’ambiente. In questa tesi uno scenario alternativo di uso del suolo per la produzione di bioenergia è stato testato: le fasce tampone bioenergetiche. Considerate le problematiche ambientali legate al trilemma “cibo-energia-ambiente”, la struttura del Millennium Ecosystem Assessment sui servizi ecosistemici (SE) fornisce l’opportunità di esaminare l’impatto ambientale di questo nuovo scenario bioenergetico. In questa tesi ho mirato a determinare in che misura le colture bioenergetiche poliennali influenzino la fornitura multipla di SE quando coltivate come fasce tampone. Per raggiungere questo obiettivo, ho combinato una revisione sistematica della letteratura sui SE forniti da colture energetiche poliennali (CEP) con una prova sperimentale su fasce tampone bioenergetiche. Applicando una metodologia di attribuzione di punteggi agli impatti sui SE estratti dal materiale bibliografico raccolto, ho mostrato come coltivando le CEP lungo i margini dei campi coltivati esista una grande opportunità per sostenere la fornitura multipla di SE. La coltivazione delle CEP come fasce tampone adiacenti a campi agricoli può migliorare i SE di regolazione del clima, dell’acqua e della biodiversità, sostenere la salute del suolo e fornire biomassa dedicata alla produzione di bioenergia. Al contrario, la conversione di margini di campo di prati stabili ha mostrato un impatto netto negativo sulla fornitura multipla di SE. Tuttavia, due sono i principali svantaggi che sono stati individuati relativamente alla creazione e alla gestione delle fasce tampone bioenergetiche. Primo, diversi sono i fattori sito-specifici di tipo idro-pedologico lungo i margini dei campi che devono essere tenuti in considerazione poiché possono avere un impatto negativo sull’affrancamento delle colture e la loro produttività a medio-lungo termine. Secondo, riguardo la catena di approvvigionamento della biomassa, uno spazio di lavoro limitato per le macchine agricole è stato riconosciuto come principale inconveniente per le fasce tampone bioenergetiche rispetto alle CEP coltivate in pieno campo. Questo limite logistico di natura spaziale può inevitabilmente incrementare i tempi e le operazioni di taglio e raccolta della biomassa e quindi in ultima il consumo di combustili fossili. Grazie ad una prova sperimentale su fasce tampone bioenergetiche condotta in un terreno sabbioso-limoso con falda acquifera poco profonda contaminata da nitrati di origine agricola, si è dimostrato come fasce tampone coltivate con miscanto e salice siano in grado di intercettare e rimuovere i nitrati in falda (>60%) tanto quanto fasce tampone con specie avventizie. CEP come miscanto e salice, grazie ai loro apparati radicali profondi, hanno mostrato essere in grado di promuovere delle relazioni pianta-suolo-microorganismi lungo l’intero profilo del suolo utili ai fini ambientali delle fasce tampone bioenergetiche. Infatti, negli strati più profondi, una maggiore biomassa radicale ha portato le CEP a superare le specie avventizie in termini di rimozione biologica dei nitrati dal suolo e mitigazione potenziale dei gas serra. Inoltre, i risultati relativi alla produzione di biomassa e le asportazioni di N legata alla fase di raccolta hanno confermato ulteriormente come la coltivazione di CEP lungo i corsi d’acqua sia una strategia win-win: produzione di biomassa e protezione dell’ambiente. In conclusione, il potenziale rivelato dalle CEP in termini di fornitura multipla di SE suggerisce che la loro coltivazione, come elementi paesaggistici perenni in posizioni strategiche all'interno di paesaggio agricolo, è un'opzione promettente per promuovere l'intensificazione ecologicamente sostenibile degli agroecosistemi. / The 21st century will challenge agriculture to feed and fuel a growing world while conserving the environment. In this thesis an alternative bioenergy land use scenario to the conversion of marginal land has been tested: the bioenergy buffers. Given the environmental issues related to “food-energy-environment” trilemma, the Millennium Ecosystem Assessment framework on ES provides an opportunity to examine the environmental impacts of this new bioenergy land use scenario. In this thesis I aimed to determine to what extent do the perennial bioenergy crops affect the delivery of multiple ES when cultivated as bioenergy buffers. To reach this aim, I combined a systematic revision of literature on ES provided by perennial bioenergy crops with a field experiment on bioenergy buffers. Applying an impact scoring methodology to the effects on ES extracted from literature, I showed that, cultivating perennial bioenergy crops along field margins of former croplands offer a great opportunity to sustain the provision of multiple ES. The cultivation of perennial bioenergy crops on field margins can improve climate, biodiversity and water regulation services, sustain soil health and provide biomass for energetic purposes. On the contrary, grassland conversion showed a net negative impact on multiple ES provision. Nevertheless, I found two main shortcomings related to bioenergy buffers establishment and management. First, several site-specific factors along field margins must be taken into account, because they can affect crop establishment and buffers long-term productivity. Second, regarding to biomass supply chain, a limited working space for the farm machinery operations has been recognized as the main disadvantages of bioenergy buffers compared to large-scale bioenergy plantations. This spatial logistics constraint may inevitably increase harvest and collection operation times and fossil fuel consumption. Conducting a field experiment with bioenergy buffers in a nitrate-enriched shallow groundwater, I showed that miscanthus and willow buffers are able to efficiently intercept and remove from groundwater the incoming NO3-N as much as buffer strips with spontaneous species. Yet, due to their deep rooting systems, bioenergy buffers promote significant plant-microbial linkages along the soil profile. At deeper soil layers, a higher fine root biomass led perennial bioenergy crops to outperform patches of adventitious vegetation in terms of biological N removal from soil and belowground GHG mitigation potential. The results on biomass production and N removal via harvesting further confirmed that the cultivation of perennial bioenergy crops along watercourses is an effective win-win strategy: biomass production and protection of the environment. In conclusion, the revealed potential of perennial bioenergy crops on multiple ES provision implies that their cultivation as perennial landscape elements in strategic locations within landscape is a promising option to promote the ecological sustainable intensification of agroecosystems. AGR/16: MICROBIOLOGIA AGRARIA AGR/13: CHIMICA AGRARIA AGR/02: AGRONOMIA E COLTIVAZIONI ERBACEE
28	Effects of increased nitrogen input on the net primary production of a tropical lower montane rain foest, Panama / Auswirkungen erhöhter Stickstoffzufuhr auf die Netto-Primärproduktion eines tropischen Bergregenwaldes in Panama Adamek, Markus 18 June 2009 (has links) No description available. 570 Biowissenschaften Biologie Forest Sciences and Forest Ecology Stickstoffdüngung tropischer Bergregenwald Netto-Primärproduktion überirdische Holzproduktion Streufall Feinwurzel-Produktion sequential coring ingrowth cores Kohlenstoff-Festlegung Eschweilera panamensis Oreomunnea mexicana Vochysia guatemalensis Panama N fertilization tropical lower montane rain forest net primary production above-ground woody biomass production litterfall fine root production sequential coring ingrowth cores carbon sequestration Eschweilera panamensis Oreomunnea mexicana Vochysia guatemalensis Panama 42.44 42.91 WNA 250: Wald Urwald {Biologie Ökologie} WNA 500: Tropische Biotope {Biologie Ökologie}
29	Impact of climate change-induced drought on tree root hydraulic properties and competition belowground / Einfluss von Bodentrockenheit auf die hydraulischen Eigenschaften und das Konkurrenzverhalten von Baumwurzeln Rewald, Boris 30 April 2008 (has links) No description available. 580 Pflanzen (Botanik) WNA 250 WVC 400 WVE 420 WVR 200 Mathematics and Natural Science Winterlinde Hainbuche Altbäume asymetrische Konkurrenz Buche Boden-Trockenheit Dach-Experiment Embolierate Feinwurzel Grobwurzel Klimawandel Olive Salzstress spezifische Leitfähigkeit Traubeneiche unterirdische Konkurrenz Xylemmorphologie Tilia cordata Carpinus betulus asymmetric competition belowground competition climate change coarse root drought stress embolism Fagus sylvatica fine root salt stress specific conductivity mature trees NaCl Olea europaea Quercus petraea roof experiment xylem morphology 42.40 42.58 42.97 43.47 43.61

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