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The application of the heat pulse velocity technique to the study of transpiration from Eucalyptus grandis.Olbrich, Bernard Wolfgang. January 1994 (has links)
This thesis examines the application of the heat pulse velocity technique (HPV) to plantation-grown Eucalyptus grandis in the Eastern Transvaal, South Africa. The work addresses the application of the technique per se and is ultimately focused on improving the prediction of the hydrological impact of afforestation, to assist in the equitable management of South Africa's limited water resources. The verification of the HPV technique on E. grandis against the cut-tree method showed that the technique accurately reflected the water uptake in four three-year-old trees and a sixteen-year-old tree. It was found that accurate measurement of wound size and probe separation was essential for accurate water use estimates. The optimal probe allocation strategy for accurate measurements of transpiration in individual trees and stands of trees was examined. Stratifying the depths of implanted probes resulted in greater precision and repeatability in the HPV-derived estimates of sap flow in E. grandis. Given a limitation in the number of probes available to estimate stand transpiration, the results showed that sampling many individuals with a low
sampling intensity (few probes per tree), rather than sampling few individuals intensively, improved the estimate of stand transpiration. An examination of the influence of tree age and season on transpiration rates showed that the transpiration rate per unit leaf area of E. grandis declined with age. Also, transpiration rates were higher in summer than under equivalent conditions of evaporative demand in winter. A seasonal change in the response of transpiration to VPD was implicated as the primary cause of this shift. A number of models were derived to predict transpiration from E. grandis. The variables vapour pressure deficit
(VPO) and photosynthetically active radiation (PAR) were found to account for a large proportion of the observed variation in transpiration from the age sequence of trees studied. The models developed are applicable to trees of varying age, but are valid only for conditions where minimal soil water stress is experienced. The derived models were tested against two sets of independent data. This confirmed that a simple linear multiple regression adequately describes the relationship between transpiration and the two driving meteorological variables, PAR and VPO, in E. grandis.
The application of a selection of the developed models on a sample data set from Sabie showed that transpiration from a three-year-old stand of E. grandis in summer may be more than double that for a sixteen-year-old stand under the same conditions. Simulated results also showed that transpiration in summer was about 25 to 50% higher than that from the same stand during winter conditions. Simulated transpiration rates from the young E. grandis stands were high, suggesting that further validation
of the estimated rates is required before the models are applied. It is concluded that the HPV method is an ideal technique to estimate water use in E. grandis trees. The models developed represent a major advancement on previous models used to predict the hydrological impact of afforestation on mountain catchments. / Thesis-(Ph.D.)-University of Natal, Durban, 1994.
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Abgabe von bodenbürtigem Lachgas über PflanzenFerch, Norbert-Jakob. Unknown Date (has links) (PDF)
Universiẗat, Diss., 2003--Hohenheim.
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Photosynthetic gas exchange responses to light, temperature, carbon dioxide and water stress, and changes in photosynthetic pigments to light and water stress in two cultivars of Hordeum vulgare LLogie, Malcolme Ronald Ruxton January 1992 (has links)
The gas exchange responses of two cultivars of Hordeum vulgare L., to light, temperature, CO₂ and water stress were investigated in the laboratory. The optimum temperature for net CO₂ assimilation was found to be 25°C and 22.5°C for cv. Clipper and cv. Dayan respectively. Net CO₂ assimilation was reduced at 30°C in cv. Dayan. At low light intensity the highest quantum yield efficiency was 0.051 mol.mol⁻¹ at 30°C for cv. Clipper, and 0.066 mol.mol⁻¹ at 20°C for cv. Dayan. At the same temperature, cv. Clipper had a higher water use efficiency than cv. Dayan, but stomatal conductance for cv. Dayan was higher than cv. Clipper. Stomatal limitation to CO₂ was lowest at the optimum temperature for CO₂ assimilation in both cultivars. Stomata limited CO₂ assimilation in cv. Clipper to a larger degree than in cv. Dayan. Relative stomatal limitation for cv. Clipper at 25°C was 0.280 ± 0.010, and for cv. Dayan at 22.5°C was 0.028 ± 0.011. Short-term exposure to elevated CO₂ concentrations increased CO₂ assimilation in both cultivars, but more so for cv. Clipper. Transpiration rate at elevated CO₂ partial pressures were higher in cv. Dayan than in cv. Clipper. At very high CO₂ (860 μmol.m⁻²s⁻¹) partial pressure water use efficiency in cv. Clipper was higher than cv. Dayan, but at low CO₂ partial pressures water use efficiency in cv. Dayan was higher than cv. Clipper. Water stress reduced the relative leaf water content and net CO₂ assimilation in both cultivars. Cultivar Dayan was more tolerant to water stress, and CO₂ assimilation in this cultivar was less affected by water stress. In both cultivars water stress increased the concentration of chlorophyll a, chlorophyll b, and chlorophyll a+b. The chlorophyll a:b ratio remained relatively constant throughout the stress period. No correlation between relative leaf water content and total carotenoid concentration was observed.
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Evapotranspiration Measurement and Simulation due to Poplar Trees at a Phytoremediation SitePanhorst, Eric M. 20 June 2000 (has links)
A railroad yard in Oneida, Tennessee was contaminated with creosote in the 1950s and 1960s through cross tie treatment. The problem was discovered in 1990 and phytoremediation in combination with an interception trench was chosen as the remediation strategy. Hybrid poplar trees (1,036) were planted in 1997 within 0.7 acres. The goals of the phytoremediation system are to prevent migration of the contaminant off the site and clean up the contaminant in-situ. This study is focused on quantifying the rate of evapotranspiration of the phytoremediation system and then determining the effect on groundwater flow. This will be accomplished by quantifying evapotranspiration using a water budget, applying White's Equation, comparing groundwater recession curves, creating a groundwater flow model, and examining water table elevations obtained at the site. Calculations of water use by the poplar trees in early September 1999 ranged from 0.62 to 1.34 gal/day/tree. The volume of evapotranspiration calculated for the trees during 1999 is 140,292 gallons. Total evapotranspiration determined by the water budget for 1998 is 1,570,064 gallons. Evaluation of the water level data over a period of several years shows significant lowering of the water table (fluctuations of up to four feet) during the summer and fall months due to evapotranspiration. Although calculated evapotranspiration rates are not as high as seen in the literature, continued monitoring of the site should show large increases in evapotranspiration rates in the future as the poplar trees mature. / Master of Science
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Evapotranspiraton Partitioning Using Stable Water Isotopes in a Semi-Arid Evergreen ForestMeuth, Jacob January 2012 (has links)
Total evapotranspiration (ET) is the key process that links the land and the atmosphere via water, energy and carbon exchange. ET is a combination of evaporation and transpiration, which behave dynamically in very different ways. In this work we investigate the relative contribution of transpiration and soil evaporation to total ET in a semi-wooded, semi-arid forest in the Manitou Research Park northwest of Colorado Springs, CO. We use stable water isotopes measured at different levels within and outside the canopy, over a 30-day period (June 26 - July 26, 2010), using a field-deployable cavity ring-down spectrometer. The traditional "Keeling plot" analysis is used to partition the ET flux from moisture that comes from outside of the ecosystem, and then a simple model is used to partition the transpiration flux. In addition, we introduce a new alternative "multi-level" method to calculate the fraction of transpiration to total ET. Both the "Keeling plot" method and the "multi-level" method yield very similar fractions of transpiration to total ET, ranging from about 15% to about 85%. We compare both methodologies and discuss some of the corrections that must be made when measuring with high-frequency field-deployable instruments.
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Cuticular Wax Biosynthesis of Lycopersicon esculentum and Its Impact on Transpiration Barrier Properties during Fruit Development / Untersuchungen zur kutikulären Wachsbiosynthese und deren Bedeutung als Transpirationsbarriere während der Fruchtentwicklung von Lycopersicon esculentumLeide, Jana January 2008 (has links) (PDF)
Cuticular waxes cover all above-ground growing parts of plants. They provide the outermost contact zone between plants and their environment and play a pivotal role in limiting transpirational water loss across the plant surface. The complex mechanisms in cuticular wax biosynthesis conferring proper barrier function still remain to be elucidated. The present study focuses on biosynthetic pathways in wax formation, cuticular wax accumulation and composition and its impact on the epidermal barrier property of the intact system of the astomatous tomato fruit (Lycopersicon esculentum Mill.). Fruits of all developmental stages of the wild type cultivar MicroTom and its lecer6 mutant defective in a β-ketoacyl-CoA synthase involved in very-long-chain fatty acid elongation were analyzed. This 'reverse genetic' approach clarified the importance of the β-ketoacyl-CoA synthase LeCER6 for epidermal barrier property in vivo on the biochemical-analytical level, on the transcriptional level and, furthermore, on the physiological level comparatively between MicroTom wild type and MicroTom lecer6. Surfaces of MicroTom wild type and MicroTom lecer6 fruits showed similar patterns of quantitative wax accumulation, but differed considerably in the permeance for water. Qualitative analyses of the chemical composition of fruit cuticular waxes in the course of fruit development revealed the meaning of the β-ketoacyl-CoA synthase deficiency in the lecer6 mutant. Fruits of this mutant exhibited a distinct decrease in the proportion of n-alkanes of chain lengths > C28. Moreover, a concomitant increase in pentacyclic triterpenoids became discernible in the mature green fruit stage of the mutant. Since quantitative changes of the cutin matrix were not sufficient to affect transpiration barrier properties of the lecer6 mutant presumably the shift in cuticular wax biosynthesis of the lecer6 mutant is responsible for the observed increase of water permeance. In order to investigate the molecular basis of wax formation, a microarray experiment was established that allows the simultaneous and comprehensive analysis of the timing and abundance of transcriptional changes in MicroTom wild type and MicroTom lecer6. This microarray consists of 167 oligonucleotides corresponding to EST and gene sequences of tomato potentially participating in wax biosynthesis, wax modification, transport processes and stress responsiveness. These parameters were correlated with the course of fruit development. This comparison of gene expression patterns showed a variety of differential expressed transcripts encoding for example lipid transfer proteins and the dehydrin TAS14. On the basis of these findings, it can be proposed that diverse regulatory mechanisms like lipid transfer processes or osmotic stress response are affected by the LeCER6 deficiency, which is primarily accompanied by an impaired water barrier property of the fruit cuticle. This present study correlates the continuous increase of LeCer6 gene expression and the accumulation of very-long-chain n-alkanes within the cuticular waxes during the transition from the immature green to the early breaker fruit phase displaying a developmental regulation of the cuticular wax biosynthesis. Organ-specific wax biosynthesis resulted in different cuticular wax pattern in tomato fruits and leaves. Moreover, in contrast to the fruits, LeCER6-deficient leaves showed a significantly reduced wax accumulation, mainly due to a decrease of n-alkanes with chain lengths > C30, while the proportion of pentacyclic triterpenoids were not affected. Deduced from these biochemical-analytical data on tomato fruits and leaves LeCER6 was characterized as a key enzyme in VLCFA biosynthetic pathway responsible for cuticular wax accumulation. In silico analysis of the LeCER6 sequence revealed the presence of two putative transmembrane domains in the N-terminal position. In addition, highly conserved configurations of catalytic residues in the active site of the enzyme were observed, which are probably essential to its overall structure and function in the fatty acid elongation process. High sequence homology of LeCER6 to the very-long-chain condensing enzymes GhCER6 of Gossypium hirsutum L. and AtCER6 of Arabidopsis thaliana (L.) Heynh. was found, which might be a good evidence for similar biochemical functions. Apart from developmental regulation of the cuticular wax biosynthesis, environmental factors influenced the cuticular wax coverage of tomato fruits. Mechanical removal of epicuticular fruit wax evoked large-scale modifications of the quantitative and qualitative wax composition, such as a reduction of aliphatic wax components, and therewith affected the cuticular water permeability. A subsequent regeneration event was included in the regular wax biosynthesis process and led to the compensation of the detached wax amounts and increased the water barrier properties of the cuticular membrane again. In contrast, water-limited conditions had only minor impact on alterations in cuticular wax biosynthesis and, consequently, on the permeance for water of tomato fruits. Floral organ fusion and conditional sterility, as observed in this study, are caused as pleiotropic effects in cell-cell signaling by the loss-of-function mutation in LeCER6. These findings corroborated the functional impact of LeCER6 on the epidermal integrity and are consistent with the current knowledge on eceriferum mutants of Arabidopsis. Investigations of phenotypic and biochemical characteristics of tomato fruits allowed a broader system-orientated perspective of the fruit development of MicroTom wild type and its lecer6 mutant. These analyses highlight more precisely alterations in the fruit surface area, fresh and dry weight, epidermal cell density, photosynthetic activity or glucose content in the course of fruit development. The differences between MicroTom wild type and MicroTom lecer6 characterize very well the large-scale consequences of the LeCER6 deficiency on the physiological status of tomato fruits. Moreover, the results clearly show a part of the genetic controlled network that governs tomato fruit metabolism and mediates extensive changes of the tomato fruit life cycle. The analyses of the stem scar tissue of the tomato fruit revealed a complex set of responses caused by the harvesting process in detail. Throughout storage of the tomato fruits barrier properties were attributed to the suberized stem scar tissue in regard to water loss limitation and reduction of the fungal infection rate. Thereby the endogenous level of abscisic acid was found to be involved in the molecular signaling pathway that regulates the de novo formation of this tissue. For the first time, the chemical composition and physiological importance could be correlated with molecular changes at the transcriptional level during suberization of the stem scar of tomato fruits. In conclusion, this work indicates a novel intact model system for an integrative functional approach for plant barrier properties that was successfully established and carefully studied. The results highlight correlations between wax biosynthesis, distribution of cuticular waxes, and its relevance on the transpirational water loss across the plant surface and, thus, promote the global understanding of plant cuticle biology. / Kutikuläre Wachse bedecken alle oberirdischen Pflanzenteile und stellen somit die Kontaktzone zwischen Pflanzen und ihrer Umwelt dar. Zudem spielen sie eine entscheidende Rolle für den Schutz der Pflanzen vor unkontrolliertem Wasserverlust. Die komplexen Mechanismen der Wachsbiosynthese, die zur dieser Barrierefunktion beitragen, sind jedoch noch weitgehend unaufgeklärt. Die vorliegende Arbeit untersucht Biosynthesewege von kutikulären Wachsen, ihre chemische Beschaffenheit sowie deren funktionelle Bedeutung als Transpirationsbarriere an dem intakten System der astomatären Tomatenfrucht (Lycopersicon esculentum Mill.). Untersuchungen wurden dabei an Früchten unterschiedlicher Entwicklungsstadien des Tomatenkultivars MicroTom Wildtyp und dessen lecer6 Mutante durchgeführt. Die lecer6 Mutante ist durch einen genetisch determinierten Defekt in der β-Ketoacyl-CoA Synthase LeCER6 unfähig zur Verlängerung von sehr langkettigen Fettsäuren. Durch diesen 'reverse genetic' Ansatz wurde der Einfluss der β-Ketoacyl-CoA Synthase LeCER6 auf die Barrierefunktion der Epidermis zunächst in vivo auf der biochemisch-analytischen und physiologischen Ebene vergleichend zwischen MicroTom Wildtyp und MicroTom lecer6 analysiert. Daran schlossen sich Untersuchungen auf transkriptioneller Ebene an. Die den Früchten von MicroTom Wildtyp und der lecer6 Mutante aufgelagerten Wachse unterscheiden sich quantitativ nur wenig, weisen hingegen deutliche Unterschiede in der qualitativen Zusammensetzung und den Wasserleitwerten auf. Die Analyse der chemischen Zusammensetzung der kutikulären Wachse zeigte im Verlauf der Fruchtentwicklung, dass die Defizienz in der β-Ketoacyl-CoA Synthase LeCER6 eine Abnahme des n-Alkananteils in den Wachsen ab einer Kettenlängen > C28 bewirkt, was bereits im Stadium der reifen grünen Früchte zu erkennen ist. Die in der lecer6 Mutante vermehrt eingelagerten pentazyklischen Triterpenoide können die Transpirationsbarriereeigenschaft der aliphatischen n-Alkane nicht adäquat ersetzen. Ein möglicher Einfluss der ebenso untersuchten Kutinmatrix der Tomatenfrucht konnte ausgeschlossen werden. Für eine umfangreiche Genexpressionsanalyse von MicroTom Wildtyp und MicroTom lecer6 wurde ein microarray Experiment konzipiert, welches 167 Oligonukleotide umfasst entsprechend zu bekannten EST- und Gensequenzen der Tomate, die möglicherweise an der Wachsbiosynthese, Wachsmodifikation, relevanten Transportprozessen oder Stressreaktionen beteiligt sind. Der Vergleich der Genexpression zwischen Wildtyp und der lecer6 Mutante zeigte eine Vielzahl von differentiell expremierten Transkripten unter anderem Lipidtransferproteine und das Dehydrin TAS14. Anhand derer kann davon ausgegangen werden, dass der Verlust der LeCER6 Funktion unterschiedliche regulative Mechanismen beeinflusst, wie zum Beispiel Lipidtransportprozesse und Reaktionen des osmotischen Stresses, die mit einer Schwächung der kutikulären Transpirationsbarriere der Fruchtepidermis einhergehen. Die vorliegende Studie belegt zudem erstmals einen Zusammenhang zwischen der Steigerung der LeCer6 Genexpression, der nur geringfügig zeitverzögerten Anreicherung sehr langkettiger n-Alkane in den kutikulären Wachsen und der daraus resultierenden Barriereleistungsfähigkeit. Ebenso wird eine Regulation der kutikulären Wachsbiosynthese in Abhängigkeit von den jeweiligen Stadien der Fruchtentwicklung veranschaulicht. Der organspezifische Vergleich der kutikulären Wachsbiosynthese zeigte, dass sich die Wachsmuster von Früchten und Blättern der Tomatenpflanzen deutlich voneinander unterscheiden. Die Wachsakkumulation auf der Blätterepidermis ist durch die LeCER6-Defizienz hauptsächlich im Anteil sehr langkettiger n-Alkane > C30 signifikant herabgesenkt, während der Gehalt an pentazyklischen Triterpenoiden jedoch nicht, so wie in den Früchten der lecer6 Mutante beobachtet, ansteigt. Aufgrund dieser Untersuchungen der Tomatenfrüchte und -blätter konnte LeCER6 als ein Schlüsselenzym für die Verlängerung sehr langkettiger Fettsäurederivate innerhalb der kutikulären Wachsbiosynthese funktionell charakterisiert werden. Anhand von vergleichenden in silico Sequenzanalysen mit den Fettsäurenelongasen GhCER6 aus Gossypium hirsutum L. und AtCER6 aus Arabidopsis thaliana (L.) Heynh. konnten sowohl zwei mögliche transmembrane Proteindomänen im N-terminalen Bereich als auch hochkonservierte Bereiche im katalytischen Zentrum des LeCER6-Enzyms lokalisiert werden, die vermutlich zur funktionellen Struktur des Enzyms beitragen. Neben der bereits angeführten entwicklungsabhängigen Regulation der Wachsbiosynthese beeinflussen auch Umweltstressoren die kutikuläre Wachsauflage der Tomatenfrüchte. Ein mechanisches Entfernen der epikutikulären Wachse führt zu einer beträchtlichen Reduktion der aliphatischen Wachsbestandteile, welche maßgeblich die Barriereeigenschaft der Kutikulamembran bestimmen. Die einsetzende Regeneration der manipulierten Wachsoberfläche führt zu einer vollständigen Kompensation der entfernten Wachskomponenten, so dass die Tomatenfrüchte in nur kurzer Zeit wieder eine dem Reifestadium entsprechende normale Verteilung der kutikulären Wachse aufweisen. Im Gegensatz dazu führt Wassermangel nur zu sehr geringfügigen qualitativen und quantitativen Veränderungen der kutikulären Wachsschicht und folglich des Wasserleitwertes der Tomatenfrüchte. Die hier dokumentierte Organfusion der Blüte und die eingeschränkte Sterilität der Tomatenpflanzen wurden als pleiotrope Effekte der lecer6 Mutation auf die Zell-Zell-Kommunikation charakterisiert, was der funktionellen Bedeutung von LeCER6 für die Epidermisintegrität entspricht und mit Beobachtungen an eceriferum Mutanten in Arabidopsis übereinstimmt. Die kombinierte Untersuchung phänotypischer und biochemischer Merkmale der Tomatenfrucht erlaubt eine breitere, systemorientierte Gegenüberstellung der Fruchtentwicklung von MicroTom Wildtyp und MicroTom lecer6. Dabei werden durch die Analysen von Größe, Frisch- und Trockengewicht, Dichte der Epidermiszellen, Photosyntheseaktivität und Glukosegehalt der Früchte die Unterschiede zwischen MicroTom Wildtyp und der lecer6 Mutante deutlich aufgezeigt. Die LeCER6-Defizienz der Mutante führt dabei zu weitreichenden Veränderungen im physiologischen Status der Frucht. Diese Ergebnisse spiegeln somit einen Teil des physiologischen Netzwerkes wider, welches weitreichende sekundäre Veränderungen im Lebenszyklus der Tomatenfrucht vermittelt. Das Stielnarbengewebe der Tomatenfrucht wird infolge der Verletzung durch den Ernteprozess gebildet. Basierend auf der de novo Suberinbiosynthese kann diesem Gewebe eine wichtige Barrierefunktion sowohl zur Einschränkung des unkontrollierten Wasserverlustes als auch zur Verringerung der Infektionsrate durch einen pilzlichen Erreger während der Lagerung von Tomatenfrüchten beigemessen werden. Eine Beteiligung der endogenen Abscisinsäure an dem der Bildung des suberinisierten Gewebes der Fruchtstielnarbe zugrunde liegendem, molekularen Signalweg konnte nachgewiesen werden. Zusammenfassend dokumentiert diese Arbeit erstmalig detaillierte Studien im Hinblick auf pflanzliche Barriereeigenschaften an einem intakten Modellsystem. Die präsentierten Ergebnisse zu molekularen Untersuchungen der Wachsbiosynthese und qualitative and quantitative Analysen der Wachsakkumulation werden im Zusammenhang des Schutzes der Pflanzenoberfläche gegen Wasserverlust durch Transpiration diskutiert und bieten somit neue Erkenntnisse über die pflanzliche Kutikula.
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Contrasting growth traits and insect interactions of two tamarix species and a hybrid (tamaricaceae) used for mine rehabilitation in South AfricaBuckham, Lael Edith 31 January 2012 (has links)
MSc., Faculty of Science, University of the Witwatersrand, 2011 / Both indigenous “Tamarix usneoides” and alien T. ramosissima co-occur in South Africa. Tamarix usneoides is potentially a metal and salt phytoremediation species. However, hybridisation is occurring between the two species and hybrids growth characteristics are deemed to be invasive. This study was undertaken at two sites on one Highveld gold mine, characterised by different soil types, where plant growth, reproductive potential and insect abundance and diversity were measured. This aims to establish the growth of T. usneoides in two site-species trials, and to identify differences between Tamarix taxa that are consistent across different environmental conditions and can be used for identification. This study also set out to establish if higher reproductive effort and enemy release are promoting the invasiveness of T. ramosissima. Trees in one site (a water logged, clayey “Glenrosa” soil) displayed significantly greater percentage survival, growth and reproductive effort than trees in the other site (a well drained, sandy “Hutton” soil). Extensive hybridisation between T. usneoides and T. ramosissima was observed with two hybrid states, morphologically similar to each parent species. The reproductive effort is consistently greater in T. ramosissima and T. ramosissima hybrid than T. usneoides and T. usneoides hybrid. After sampling 217 trees in this study, the three characteristics of (1) insertion of filaments into the nectar disc, (2) petal shape and (3) presence of salt glands on leaves most accurately distinguished between T. usneoides and T. ramosissima taxa. Three insect species have been identified from this study as potentially damaging agents on Tamarix spp. Insects can discern between the Tamarix tree taxa and T. ramosissima is being released from insect herbivore pressure, as very few insects and a lower diversity were recorded on T. ramosissima and its hybrids (T. ramosissima hybrids > T. ramosissima). To achieve phytoremediation objectives, careful tree identification and selection of genetically pure individuals for cloning is recommended. Additionally the removal of existing alien and hybrid plants, and further research to find a suitable host specific insect biological agent to control alien Tamarix is necessary.
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Determination of empirical parameters for root water uptake models / Determinação de parâmetros empíricos para modelos de extração de água do soloSantos, Marcos Alex dos 18 January 2016 (has links)
Physical root water uptake models can provide more insight into the mechanism, but their physical plant hydraulic parameters are hardly-ever available, making them less attractive in practical applications. Conversely, empirical root water uptake modes are more readily used because of their simplicity and lower data requirements, but their empirical parameters and ability in describing the dynamics of root water uptake need further investigation. Combining physical and empirical models might be an effective way to address these issues. In this thesis, it is tested the feasibility of deriving parameters for empirical root water uptake models by using predictions performed by an enhanced mechanistic root water uptake model. It is also reviewed the major root water uptake models that have been used together with larger eco-hydrological models and some alternatives are also presented. All these models are analyzed for different scenarios concerning soil type, atmospheric demand and root length density. Evaluation was performed by optimizing their empirical parameters so that the best fitting with the physical model is achieved. At last, further analyzes are performed for an empirical model pointed at the previous analyzes, and the empirical parameters for this model are provided for different scenarios regarding soil type, root length density R, rooting depth and potential transpiration Tp as well as for three levels of radial root hydraulic conductivity. It is shown that (i) the largely-used Feddes empirical root water uptake model performs well only under circumstances of low R -- that is for the scenarios of low root water uptake \"compensation\"-- and from medium to hight R, the model can not mimic properly the root uptake dynamics as predicted by the physical model; (ii) the Jarvis model provides good predictions only for low and medium R scenarios and for high R the model can not mimic the uptake patterns predicted by the physical model; Using the proposed reduction function in Jarvis model, that is the JMm model, helps to improve water uptake predictions; (iii) the proposed models are capable of predicting similar root water uptake patterns by the physical model and the statistical indices point them as the best alternatives to mimic root water uptake predictions by the physical model; (iv) the parameters of empirical models can be retrieved in a single experiment of soil drying-out by defining the objective function in terms of root water uptake; (v) the empirical parameters provided by the proposed model varies with the scenarios as well as its overall performance. / Embora modelos físicos de extração de água do solo sejam importantes para analisar detalhes mecanísticos do sistema, seus parâmetros hidráulicos não são facilmente disponíveis, e assim são menos utilizados em situações práticas. Entretanto, modelos empíricos são facilmente aplicados devido a sua simplicidade e baixo requerimento de dados, porém seus parâmetros empíricos e habilidade em descrever a dinâmica da extração de água do solo precisa ser mais investigada. O uso combinado de modelos empíricos e físicos pode ser útil nesse contexto. O objetivo geral deste trabalho é testar se os parâmetros de modelos empíricos de extração de água do solo podem ser determinados através de simulações feitas como um modelo físico de extração de água do solo. Fez-se uma revisão sobre os principais modelos empíricos usados em modelos hidrológicos, assim como algumas alternativas foram apresentadas. Alguns desses modelos foram analisados para diferentes cenários de tipo de solo, demanda atmosférica e densidade de comprimento de raiz R. A análise foi feita otimizando-se os parâmetros empíricos dos modelos a fim de obter o melhor ajuste com o modelo físico. Em seguida, fez-me uma análise mais detalhada sobre o desempenho de um modelo empírico sugerido nas analises anteriores, como o objetivo de fornecer os valores de seus parâmetros empíricos para diferentes cenários de tipo de solo, R, profundidade do sistema radicular e transpiração potencial. Analisou-se também a variação desses parâmetros empíricos em função da condutividade hidráulica da raiz. Os resultados mostraram que (i) o modelo empírico de Feddes, que é largamente utilizado, só apresenta bom desempenho em cenários de baixo R -- ou seja, para cenários com baixa compensação de extração de água do solo-- e, para cenários de médio a alto R, o modelo não é capaz de representar adequadamente o dinâmica de extração de água do solo simulada pelo modelo físico; (ii) O modelo de Jarvis só apresenta desempenho adequado em cenários de baixo R e, para alto R, o modelo não é capaz de representar adequadamente a distribuição de extração simulada pelo modelo físico; (iii) inserindo-se a função de redução proposta no presente trabalho no modelo de Jarvis, ou seja o modelo JMm, proporciona melhores estimativas da distribuição de extração de água do solo; (iv) Os modelos propostos apresentam o melhor desempenho em descrever as predições feitas pelo modelo físico; (v) os parâmetros dos modelos empíricos podem ser obtidos em um único experimento de secagem do solo, definindo-se a função objetivo em função da extração de água do solo; (vi) Os parâmetros empíricos do modelo proposto variam em função dos cenários avaliados.
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The effect of non-ionic surfactants on water use and plant growth of Chrysanthemum x morifolium Ramat 'Florida marble'Bowles, John Paul January 2011 (has links)
Photocopy of typescript. / Digitized by Kansas Correctional Industries
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Relations Between Transpiration, Leaf Temperatures, and Some Environmental FactorsTew, Ronald Kay 01 May 1962 (has links)
Transpiration is the loss of water in vapor form from a plant. This is essentially the same process as evaporation except that it is modified by plant structure. Large quantities of water are removed from the soil, transferred through the conducting tissues of the plant, and dissipated into the air each day. As soon as the water is lost to the atmosphere, it becomes unavailable for human use.
Few people are aware of the actual magnitude of this process. Over 95 percent of the water absorbed by the plant is lost through transpiration, the other 5 percent being used in photosynthesis and as a plant constituent. Herbaceous plants may transpire several times their own volume of water in a single day. Many forests lose over 20 inches of water in a year. Such large quantities, when dissipated in vapor form, are sufficient to modify the climate in the surrounding area.
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