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191	Développement de modèles physiques pour comprendre la croissance des plantes en environnement de gravité réduite pour des apllications dans les systèmes support-vie / Developing physical models to understand the growth of plants in reduced gravity environments for applications in life-support systems Poulet, Lucie 11 July 2018 (has links) Les challenges posés par les missions d’exploration du système solaire sont très différents de ceux de la Station Spatiale Internationale, puisque les distances sont beaucoup plus importantes, limitant la possibilité de ravitaillements réguliers. Les systèmes support-vie basés sur des plantes supérieures et des micro-organismes, comme le projet de l’Agence Spatiale Européenne (ESA) MELiSSA (Micro Ecological Life Support System Alternative) permettront aux équipages d’être autonomes en termes de production de nourriture, revitalisation de l’air et de recyclage d’eau, tout en fermant les cycles de l’eau, de l’oxygène, de l’azote et du carbone, pendant les missions longue durée, et deviendront donc essentiels.La croissance et le développement des plantes et autres organismes biologiques sont fortement influencés par les conditions environnementales (par exemple la gravité, la pression, la température, l’humidité relative, les pressions partielles en O2 et CO2). Pour prédire la croissance des plantes dans ces conditions non-standard, il est crucial de développer des modèles de croissance mécanistiques, permettant une étude multi-échelle des différents phénomènes, ainsi que d’acquérir une compréhension approfondie de tous les processus impliqués dans le développement des plantes en environnement de gravité réduite et d’identifier les lacunes de connaissance.En particulier, les échanges gazeux à la surface de la feuille sont altérés en gravité réduite, ce qui pourrait diminuer la croissance des plantes dans l’espace. Ainsi, nous avons étudié les relations complexes entre convection forcée, niveau de gravité et production de biomasse et avons trouvé que l’inclusion de la gravité comme paramètre dans les modèles d’échanges gazeux des plantes nécessite une description précise des transferts de matière et d’énergie dans la couche limite. Nous avons ajouté un bilan d’énergie au bilan de masse du modèle de croissance de plante déjà existant et cela a ajouté des variations temporelles sur la température de surface des feuilles.Cette variable peut être mesurée à l’aide de caméras infra-rouges et nous avons réalisé une expérience en vol parabolique et cela nous a permis de valider des modèles de transferts gazeux locaux en 0g et 2g, sans ventilation.Enfin, le transport de sève, la croissance racinaire et la sénescence des feuilles doivent être étudiés en conditions de gravité réduite. Cela permettrait de lier notre modèle d’échanges gazeux à la morphologie des plantes et aux allocations de ressources dans une plante et ainsi arriver à un modèle mécanistique complet de la croissance des plantes en environnement de gravité réduite. / Challenges triggered by human space exploration of the solar system are different from those of the International Space Station because distances and time frames are of a different scale, preventing frequent resupplies. Bioregenerative life-support systems based on higher plants and microorganisms, such as the ESA Micro-Ecological Life Support System Alternative (MELiSSA) project will enable crews to be autonomous in food production, air revitalization, and water recycling, while closing cycles for water, oxygen, nitrogen, and carbon, during long-duration missions and will thus become necessary.The growth and development of higher plants and other biological organisms are strongly influenced by environmental conditions (e.g. gravity, pressure, temperature, relative humidity, partial pressure of O2 or CO2). To predict plant growth in these non-standard conditions, it is crucial to develop mechanistic models of plant growth, enabling multi-scale study of different phenomena, as well as gaining thorough understanding on all processes involved in plant development in low gravity environment and identifying knowledge gaps.Especially gas exchanges at the leaf surface are altered in reduced gravity, which could reduce plant growth in space. Thus, we studied the intricate relationships between forced convection, gravity levels and biomass production and found that the inclusion of gravity as a parameter in plant gas exchanges models requires accurate mass and heat transfer descriptions in the boundary layer. We introduced an energy coupling to the already existing mass balance model of plant growth and this introduced time-dependent variations of the leaf surface temperature.This variable can be measured using infra-red cameras and we implemented a parabolic flight experiment, which enabled us to validate local gas transfer models in 0g and 2g without ventilation.Finally, sap transport needs to be studied in reduced gravity environments, along with root absorption and leaf senescence. This would enable to link our gas exchanges model to plant morphology and resources allocations, and achieve a complete mechanistic model of plant growth in low gravity environments. Systèmes support-vie biorégénératifs Modèle mécanistique Gravité réduite Exploration spatiale Plantes Flux énergétiques Écosystèmes artificiels Échanges gazeux Transpiration Température foliaire Images infra-rouges Vol parabolique Bioregenerative Life-Support Systems Mechanistic modeling Low gravity Space exploration Plants Energy fluxes Artificial ecosystems Gas exchanges Transpiration Leaf temperature Infra-red images Parabolic flight
192	Etude mathématique de modèles de couches visqueuses pour des écoulements naturels / Mathematical study of viscous layer models for natural ows Legrand, Mathilde 03 November 2016 (has links) Le système de Saint Venant est répandu pour modéliser des fluides dont la hauteur est inférieure au domaine d'écoulement. Son écriture nécessite des hypothèses sur le profil de vitesse pour connaître le flux de la quantité de mouvement ainsi que le cisaillement sur le fond. Dans cette thèse, nous nous sommes intéressés à un couplage entre un fluide parfait et une couche visqueuse dans l'esprit des couches limites interactives (IBL) introduites en aéronautique. Cette interaction nous permet de proposer un terme de friction en adéquation avec les attentes physiques au regard de la position du maximum local. Une part importante de cette thèse est donc consacrée à la compréhension de la couche visqueuse dans laquelle la recherche du profil de vitesse est cantonnée. Cette étude se décompose en l'écriture des équations de Prandtl puis en l'établissement de l'équation de von Kármán. Cette dernière met en jeu les quantités nécessaires à la définition du flux recherché et est donc un élément clé de la fermeture du système. Des résultats numériques viennent illustrer le modèle obtenu par le couplage entre le fluide parfait et la couche visqueuse. Le dernier chapitre expose deux formulations alternatives obtenues d'un point de vue d'un écoulement d'un fluide parfait dont les conditions sur les bords du domaine sont modifiées, soit par une condition de transpiration définie sur le fond, soit par une modification du domaine enlien avec une topographie apparente. / Shallow Water system is widely used for flows when the depth is smaller than the longitudinal scale. The establishment needs some hypothesis on the velocity profile in order to describe the moment flux and the shear stress on ground. In this thesis, we present a two layer decomposition of the fluid between an ideal fluid and a viscous layer in the spirit of the Interactive Boundary Layer (IBL) introduced in aeronautics. This interaction leads to obtain in our equations a friction term which fits with the physical expectations for the local maximum. So a major part of this work is interested in the comprehension of the viscous layer where the velocity profile is confined. The study is based on the writing of Prandtl equations then the establishment of the von Kármán equation. The last one contains the necessary quantities for a definition of the researched flux. Also this equation is essential for a closure of the system. Some numerical results illustrate the proposed model with the association of ideal fluid ans viscous layer. A last chapter presents two alternatives formulations of the model based on an ideal fluid with modified boundary conditions. The first one keeps the same domain but has a transpiration boundary. Eaux peu profondes Fluide parfait Couche visqueuse Couche limite Epaisseur de déplacement Friction Condition de transpiration Topographie apparente Equation de von Kármán Equations de Prandtl Shallow water Ideal fluid Viscous layer Boundary layer Displacement thickness Friction Transpiration boundary condition Apparent topography Von Kármán equation Prandtl equations 515.353
193	Surface Conductance of Five Different Crops Based on 10 Years of Eddy-Covariance Measurements Spank, Uwe, Köstner, Barbara, Moderow, Uta, Grünwald, Thomas, Bernhofer, Christian 16 January 2017 (has links) The Penman-Monteith (PM) equation is a state-of-the-art modelling approach to simulate evapotranspiration (ET) at site and local scale. However, its practical application is often restricted by the availability and quality of required parameters. One of these parameters is the canopy conductance. Long term measurements of evapotranspiration by the eddy-covariance method provide an improved data basis to determine this parameter by inverse modelling. Because this approach may also include evaporation from the soil, not only the ‘actual’ canopy conductance but the whole surface conductance (gc) is addressed. Two full cycles of crop rotation with five different crop types (winter barley, winter rape seed, winter wheat, silage maize, and spring barley) have been continuously monitored for 10 years. These data form the basis for this study. As estimates of gc are obtained on basis of measurements, we investigated the impact of measurements uncertainties on obtained values of gc. Here, two different foci were inspected more in detail. Firstly, the effect of the energy balance closure gap (EBCG) on obtained values of gc was analysed. Secondly, the common hydrological practice to use vegetation height (hc) to determine the period of highest plant activity (i.e., times with maximum gc concerning CO2-exchange and transpiration) was critically reviewed. The results showed that hc and gc do only agree at the beginning of the growing season but increasingly differ during the rest of the growing season. Thus, the utilisation of hc as a proxy to assess maximum gc (gc,max) can lead to inaccurate estimates of gc,max which in turn can cause serious shortcomings in simulated ET. The light use efficiency (LUE) is superior to hc as a proxy to determine periods with maximum gc. Based on this proxy, crop specific estimates of gc,maxcould be determined for the first (and the second) cycle of crop rotation: winter barley, 19.2 mm s−1 (16.0 mm s−1); winter rape seed, 12.3 mm s−1 (13.1 mm s−1); winter wheat, 16.5 mm s−1 (11.2 mm s−1); silage maize, 7.4 mm s−1 (8.5 mm s−1); and spring barley, 7.0 mm s−1 (6.2 mm s−1). info:eu-repo/classification/ddc/550 ddc:550
194	Physiological responses and soil water balance of clonal Eucalyptus under contrasting spacings and genotypes / Respostas fisiológicas e balanço hídrico do solo em Eucalyptus clonais sob espaçamentos de plantio e genótipos contrastantes Hakamada, Rodrigo Eiji 22 September 2016 (has links) Planting density and genotype have close relationship with the water relations in plants. The scenario of increased occurrence of extreme weather events and the change of Eucalyptus forest plantations to high water deficit regions, led us to the three key questions of this study: (1) What is the relationship between planting density and the potential water stress? (2) The planting spacing interferes the water use efficiency (WUE), i.e. the amount of biomass produced by the amount of water transpired? (3) Can the planting density change the soil water balance (BHS)? To develop this work, we settled a field trial in Mogi Guacu, SP, in February 2012. We planted four genetic material (Eucalyptus grandis x E.urophylla1 {Urograndis1}, Eucalyptus grandis x E.urophylla2, E.urophylla and E.grandis x E.camaldulensis {Grancam}) with different levels of tolerance to drought and four planting spacings (3.4, 7.0, 10.5 and 16.9 m2 plant-1, which correspond to densities of 2,949 , 1,424 and 1,028 and 591 plants ha-1). In Chapter 1, we evaluated the leaf water potential (representing potential water stress) of the four clones for 1 year, between 1.5 and 2.5 years. Regardless of the genetic material, the higher the wood productivity, the greater the leaf water potential. The denser planting (2,949 plants ha-1) stands generated 39% more wood, however, water stress potential reached up to 33% higher than the least dense planting (591 plants ha-1). In the second chapter, during the same period, we evaluated the efficiency of water use, which did not vary according to the change of planting density, but showed differences between genotypes with US 2.3, 2.2 and 1, 5 g L-1 to Urograndis, Urophylla and Grancam, respectively, at a density of 1,424 plants ha-1. Finally, the third chapter evaluated for two years, between 1.7 and 3.7 years, transpiration (T), soil evaporation (Es) and canopy interception (Ei), which together made up evapotranspiration (ET). Subtraction of precipitation (P) per ET resulted in soil water balance (SWB). The SWB was positive or near zero for the two clones evaluated (Urograndis1 and Grancam) when planting density was less than or equal to 1,028 trees ha-1. In the denser planting, the balance was -25%. These studies show that: a higher wood growth results in a higher potential drought stress, generating a clear trade-off between production and survival of trees. However, the detailed study of genetic materials fall under that there are increasing opportunities in water use efficiency, though without the increase in water use, bringing a greater share of water in the watershed scale. Finally, plantations above 1,028 ha-1 trees resulted in a negative soil water balance of -25% at the peak of growth. Together, this study reveals that spacing associated with genotypes can serve as tools in the search for balance between timber production and conservation of natural resources. / A densidade de plantio e o genótipo possuem estreita relação com as relações hídricas nas plantas. Sob um cenário de maior ocorrência de eventos climáticos extremos e do avanço dos plantios florestais de eucalipto para regiões de elevado déficit hídrico, elaboramos três perguntas-chave para esse estudo: (1) Qual a relação entre a densidade de plantio e o potencial estresse hídrico? (2) O espaçamento de plantio interfere na eficiência do uso da água (EUA), i.e., na quantidade de biomassa produzida pela quantidade de água transpirada? (3) Pode a densidade de plantio alterar o balanço hídrico do solo (BHS)? Para responder a essas questões, instalou-se um ensaio de campo em Mogi Guacu, SP, em fevereiro de 2012. Foram plantados quatro materiais genéticos (Eucalyptus grandis x E.urophylla1 {Urograndis1}, Eucalyptus grandis x E.urophylla2, E.urophylla e E.grandis x E.camaldulensis {Grancam}) com distintos níveis de tolerância à seca e quatro espaçamentos de plantio (3,4, 7,0, 10,5 e 16,9 m2 planta-1, que correspondem às densidades de 2.949, 1.424 e 1.028 e 591 plantas ha-1). No capítulo 1, avaliou-se o potencial hídrico foliar (representando o potencial estresse hídrico) dos quatro clones durante 1 ano, entre 1,5 e 2,5 anos. Independentemente do material genético, quanto maior a produtividade madeireira atingida, maior o potencial hídrico foliar. Os plantios mais adensados (2.949 plantas ha-1) geraram povoamentos 39% mais produtivos, no entanto, o potencial estresse hídrico chegou a atingir 33% acima do plantio menos adensado (591 plantas ha-1). No segundo capítulo, durante o mesmo período, avaliou-se a eficiência do uso da água, que não variou conforme a mudança de densidade de plantio, mas apresentou diferença entre os genótipos, com EUA de 2,3, 2,2 e 1,5 g L-1 para os clones Urograndis, Urophylla e Grancam, respectivamente, na densidade de 1.424 plantas ha-1. Por fim, o terceiro capítulo avaliou durante dois anos, entre 1,7 e 3,7 anos, a transpiração (T), evaporação do solo (Es) e interceptação de água pela copa (Ei), que somados compunham e evapotranspiração (ET). A subtração da precipitação (P) da ET resultou no balanço hídrico do solo (BHS). O BHS foi positivo ou próximo de zero para os dois clones avaliados (Urograndis1 e Grancam) quando a densidade de plantio foi inferior ou igual a 1.028 árvores ha-1. No plantio mais adensado, o balanço foi de -25%. Estes estudos demonstram que: a maior produtividade madeireira acarreta em maior potencial estresse hídrico, gerando um claro dilema entre a produção e a sobrevivência dos plantios. No entanto, o estudo detalhado dos materiais genéticos releva que há possibilidades de incremento na eficiência do uso da água sem que ocorra o aumento no uso da água, trazendo um maior compartilhamento da água na escala da microbacia. Por fim, plantios acima de 1.028 árvores ha-1 resultaram em um balanço hídrico do solo negativo médio de -25% no pico do crescimento. Em conjunto, o presente trabalho releva que o espaçamento associado a materiais genéticos específicos, podem servir como ferramenta na busca pelo equilíbrio entre a produção madeireira e a conservação de recursos naturais. Canopy interception Densidade de plantio Eficiência de uso da água Evaporação do solo Florestas plantadas Interceptação da copa Leaf water potential Plantation forests Planting density Potencial hídrico foliar Soil evaporation Transpiração Transpiration Uso de água Water use Water use efficiency
195	Physiological responses and soil water balance of clonal Eucalyptus under contrasting spacings and genotypes / Respostas fisiológicas e balanço hídrico do solo em Eucalyptus clonais sob espaçamentos de plantio e genótipos contrastantes Rodrigo Eiji Hakamada 22 September 2016 (has links) Planting density and genotype have close relationship with the water relations in plants. The scenario of increased occurrence of extreme weather events and the change of Eucalyptus forest plantations to high water deficit regions, led us to the three key questions of this study: (1) What is the relationship between planting density and the potential water stress? (2) The planting spacing interferes the water use efficiency (WUE), i.e. the amount of biomass produced by the amount of water transpired? (3) Can the planting density change the soil water balance (BHS)? To develop this work, we settled a field trial in Mogi Guacu, SP, in February 2012. We planted four genetic material (Eucalyptus grandis x E.urophylla1 {Urograndis1}, Eucalyptus grandis x E.urophylla2, E.urophylla and E.grandis x E.camaldulensis {Grancam}) with different levels of tolerance to drought and four planting spacings (3.4, 7.0, 10.5 and 16.9 m2 plant-1, which correspond to densities of 2,949 , 1,424 and 1,028 and 591 plants ha-1). In Chapter 1, we evaluated the leaf water potential (representing potential water stress) of the four clones for 1 year, between 1.5 and 2.5 years. Regardless of the genetic material, the higher the wood productivity, the greater the leaf water potential. The denser planting (2,949 plants ha-1) stands generated 39% more wood, however, water stress potential reached up to 33% higher than the least dense planting (591 plants ha-1). In the second chapter, during the same period, we evaluated the efficiency of water use, which did not vary according to the change of planting density, but showed differences between genotypes with US 2.3, 2.2 and 1, 5 g L-1 to Urograndis, Urophylla and Grancam, respectively, at a density of 1,424 plants ha-1. Finally, the third chapter evaluated for two years, between 1.7 and 3.7 years, transpiration (T), soil evaporation (Es) and canopy interception (Ei), which together made up evapotranspiration (ET). Subtraction of precipitation (P) per ET resulted in soil water balance (SWB). The SWB was positive or near zero for the two clones evaluated (Urograndis1 and Grancam) when planting density was less than or equal to 1,028 trees ha-1. In the denser planting, the balance was -25%. These studies show that: a higher wood growth results in a higher potential drought stress, generating a clear trade-off between production and survival of trees. However, the detailed study of genetic materials fall under that there are increasing opportunities in water use efficiency, though without the increase in water use, bringing a greater share of water in the watershed scale. Finally, plantations above 1,028 ha-1 trees resulted in a negative soil water balance of -25% at the peak of growth. Together, this study reveals that spacing associated with genotypes can serve as tools in the search for balance between timber production and conservation of natural resources. / A densidade de plantio e o genótipo possuem estreita relação com as relações hídricas nas plantas. Sob um cenário de maior ocorrência de eventos climáticos extremos e do avanço dos plantios florestais de eucalipto para regiões de elevado déficit hídrico, elaboramos três perguntas-chave para esse estudo: (1) Qual a relação entre a densidade de plantio e o potencial estresse hídrico? (2) O espaçamento de plantio interfere na eficiência do uso da água (EUA), i.e., na quantidade de biomassa produzida pela quantidade de água transpirada? (3) Pode a densidade de plantio alterar o balanço hídrico do solo (BHS)? Para responder a essas questões, instalou-se um ensaio de campo em Mogi Guacu, SP, em fevereiro de 2012. Foram plantados quatro materiais genéticos (Eucalyptus grandis x E.urophylla1 {Urograndis1}, Eucalyptus grandis x E.urophylla2, E.urophylla e E.grandis x E.camaldulensis {Grancam}) com distintos níveis de tolerância à seca e quatro espaçamentos de plantio (3,4, 7,0, 10,5 e 16,9 m2 planta-1, que correspondem às densidades de 2.949, 1.424 e 1.028 e 591 plantas ha-1). No capítulo 1, avaliou-se o potencial hídrico foliar (representando o potencial estresse hídrico) dos quatro clones durante 1 ano, entre 1,5 e 2,5 anos. Independentemente do material genético, quanto maior a produtividade madeireira atingida, maior o potencial hídrico foliar. Os plantios mais adensados (2.949 plantas ha-1) geraram povoamentos 39% mais produtivos, no entanto, o potencial estresse hídrico chegou a atingir 33% acima do plantio menos adensado (591 plantas ha-1). No segundo capítulo, durante o mesmo período, avaliou-se a eficiência do uso da água, que não variou conforme a mudança de densidade de plantio, mas apresentou diferença entre os genótipos, com EUA de 2,3, 2,2 e 1,5 g L-1 para os clones Urograndis, Urophylla e Grancam, respectivamente, na densidade de 1.424 plantas ha-1. Por fim, o terceiro capítulo avaliou durante dois anos, entre 1,7 e 3,7 anos, a transpiração (T), evaporação do solo (Es) e interceptação de água pela copa (Ei), que somados compunham e evapotranspiração (ET). A subtração da precipitação (P) da ET resultou no balanço hídrico do solo (BHS). O BHS foi positivo ou próximo de zero para os dois clones avaliados (Urograndis1 e Grancam) quando a densidade de plantio foi inferior ou igual a 1.028 árvores ha-1. No plantio mais adensado, o balanço foi de -25%. Estes estudos demonstram que: a maior produtividade madeireira acarreta em maior potencial estresse hídrico, gerando um claro dilema entre a produção e a sobrevivência dos plantios. No entanto, o estudo detalhado dos materiais genéticos releva que há possibilidades de incremento na eficiência do uso da água sem que ocorra o aumento no uso da água, trazendo um maior compartilhamento da água na escala da microbacia. Por fim, plantios acima de 1.028 árvores ha-1 resultaram em um balanço hídrico do solo negativo médio de -25% no pico do crescimento. Em conjunto, o presente trabalho releva que o espaçamento associado a materiais genéticos específicos, podem servir como ferramenta na busca pelo equilíbrio entre a produção madeireira e a conservação de recursos naturais. Densidade de plantio Eficiência de uso da água Evaporação do solo Florestas plantadas Interceptação da copa Potencial hídrico foliar Transpiração Uso de água Canopy interception Leaf water potential Plantation forests Planting density Soil evaporation Transpiration Water use Water use efficiency
196	Características agronômicas e índices de trocas gasosas do tomateiro em função de sistemas de condução em ambiente protegido / Agronomic characteristics and gas exchange rates of tomato in function of cultivation system in a protected environment Hachmann, Tiago Luan 26 February 2015 (has links) Made available in DSpace on 2017-07-10T17:37:00Z (GMT). No. of bitstreams: 1 Tiago_Luan_Hachmann.pdf: 1649541 bytes, checksum: 8e937bb39bf1fdae7f31d4186d79cc60 (MD5) Previous issue date: 2015-02-26 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / This work was conducted in the period from April, 11th, 2014 until September, 9th, 2014 aiming studying the influence of the number of stems and the way of establishing these stems in productivity and quality characteristics of the tomato cultivars, and evaluate the daily course of gas exchange indexes of the tomato cultivars in the leaves exposed to solar radiation from the east (morning) or the west (afternoon). The experimental design used in the first experiment was a randomized block design with factorial 3 x 2 x 2, with four replications. Three numbers of stem per plant were tested (one, two and four steams) two forms of establishment (maintaining and removing the main stem) and two cultivars (Caniles and Rubi F1 hybrid). The total number of fruits, number of normal fruits, non-commercial and blossom-end rot was evaluated; percentage of unmarketable fruits and blossom end rot; average mass, longitudinal and transversal diameter of the normal fruits; fruit mass, transversal and longitudinal diameter, average fruit mass and productivity of the first four clusters; total mass of fruit and fruit normal mass; and was calculated productivity of normal fruits, non-commercial, with blossom end rot and total fruit yield. It was also evaluated pH, soluble solids, titratable acidity and soluble solids/titratable acidity ("ratio"). In the second experiment the experimental design was a randomized block design, factorial 2 x 2 x 6, with four replications. The first factor was composed of two evaluation positions in the plant (East and West), the second of two tomato cultivars (Caniles and Rubi) and finally six times evaluation throughout the day (8:00, 10:00, 12:00, 14:00, 16:00 and 18:00). It was measured the rate of CO2 net assimilation (A), leaf transpiration (E), stomatal conductance (gs), internal CO2 concentration (Ci) and leaf temperature (°C) and vapor pressure deficit. It was also calculated the water use efficiency (WUE) (A/E), intrinsic water use efficiency (WUEi) (A/gs) and the instantaneous efficiency of carboxylation (A/Ci). The conduction of plants with four steams is more favorable to productivity and the quality characteristics. The establishment of steams number keeping the main stem is best suited for providing greater productivity. The cultivar Caniles is the most suitable for driving on growing conditions, due to its higher yield and fruits with better "ratio". The values of net assimilation rate of CO2, leaf transpiration, stomatal conductance, leaf temperature, water use efficiency, intrinsic water use efficiency and instantaneous carboxylation efficiency on the east side are larger than on the west side. The cultivar Caniles has a higher net assimilation rate of CO2, leaf transpiration, leaf temperature and instantaneous carboxylation efficiency under conditions of high temperature and luminosity / Este trabalho foi conduzido no período de 11/04/2014 a 16/09/2014, tendo como objetivo estudar a influência do número de hastes e da forma de estabelecimento dessas hastes nas características produtivas e qualitativas de duas cultivares de tomateiro, e avaliar o curso diário dos índices de trocas gasosas de duas cultivares de tomateiro, em folhas expostas à radiação solar proveniente do quadrante leste (período da manhã) ou do quadrante oeste (período da tarde). O delineamento experimental utilizado no primeiro experimento foi de blocos casualizados, em esquema fatorial de 3 x 2 x 2, com quatro repetições. Foram testados três números de haste por planta (uma, duas e quatro hastes), duas formas de condução (mantendo a haste principal e retirando a haste principal) e duas cultivares (híbrido F1 Rubi e híbrido Caniles). Foi avaliado o número total de frutos, número de frutos normais, não comerciais e com podridão apical; porcentagem de frutos não comerciais e com podridão apical; massa média, diâmetro longitudinal e transversal dos frutos normais; massa de frutos, diâmetro transversal e longitudinal, massa média por fruto e produtividade dos quatro primeiros cachos; massa total de frutos e massa de frutos normais; e foi calculada a produtividade de frutos normais, não comerciais, com podridão apical e produtividade total de frutos. Também foi avaliado o pH, teor de sólidos solúveis, acidez titulável e a relação sólidos solúveis/acidez titulável ( ratio ). No segundo experimento o delineamento experimental utilizado foi de blocos ao acaso, em esquema fatorial 2 x 2 x 6, com quatro repetições. O primeiro fator foi composto de duas posições de avaliação na planta (Leste e Oeste), o segundo de duas cultivares de tomate (Caniles e Rubi) e por fim seis horários de avaliação ao longo do dia (8:00, 10:00, 12:00, 14:00, 16:00 e 18:00). Foi mensurada a taxa de assimilação líquida de CO2 (A), taxa de transpiração foliar (E), condutância estomática (gs), concentração interna de CO2 (Ci), temperatura foliar (°C) e déficit de pressão de vapor. Também foi calculada a eficiência no uso da água (WUE) (relação A/E), eficiência intrínseca no uso da água (WUEi) (relação A/gs) e a eficiência instantânea da carboxilação (A/Ci) (relação A/Ci). A condução das plantas com quatro hastes é mais favorável para a produtividade e para as características de qualidade. O estabelecimento do número de hastes mantendo a haste principal é mais adequado por proporcionar obtenção de maior produtividade. A cultivar Caniles é a mais adequada para a condução nas condições de cultivo, por apresentar maior produtividade e por apresentar frutos com maior ratio . Os valores de taxa de assimilação líquida de CO2, taxa de transpiração foliar, condutância estomática, temperatura foliar, eficiência no uso da água, eficiência intrínseca no uso da água e eficiência instantânea de carboxilação no quadrante leste são maiores que no quadrante oeste. A cultivar Caniles apresenta maior taxa de assimilação líquida de CO2, taxa de transpiração foliar, temperatura foliar e eficiência instantânea de carboxilação sob condições de temperatura e luminosidade elevadas Solanum lycopersicum L. Densidade de plantio Número de hastes Taxa de assimilação líquida de CO2 Taxa de transpiração foliar Solanum lycopersicum L. Planting density Number of stems Gas exchange CO2 net assimilation Leaf transpiration rate CIÊNCIAS AGRÁRIAS:AGRONOMIA
197	Physiological mechanisms involved in water use efficiency in grapevines Tomás Mir, Magdalena 02 July 2012 (has links) La sequera és una de les majors limitacions per a l’agricultura en general, factor que pot incrementar d’acord amb les prediccions del canvi climàtic. Per això, reduir l’ús de l’aigua en el reg i augmentar l’eficiència en l’ús de l’aigua (EUA) constitueix una de les majors prioritats per aconseguir una agricultura sostenible. L’EUA és un balanç entre guanys de biomassa i les despeses d’aigua. Aquesta Tesi s’ha centrat en l’estudi de 3 dels processos fisiològics que afecten a l’ús de l’aigua i a la producció de la planta en el cas de la vinya, i que per tant poden ser considerats factors potencials per millorar l’EUA: (1) conductància del mesòfil, (2) transpiració nocturna (3) respiració. Els resultats d’aquesta Tesi revelen que la conductància del mesòfil i la respiració són els principals components per millorar l’EUA permetent millorar l’assimilació de carboni o minimitzant les pèrdues del carboni fixat per la fotosíntesis Fisiologia vegetal 57 58
198	Assessing the Bare Soil Evaporation Via Surface Temperature Measurements Idso, Sherwood B., Reginato, Robert J., Jackson, Ray D. 12 April 1975 (has links) From the Proceedings of the 1975 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 11-12, 1975, Tempe, Arizona / Evaporation of water from bare soils is an important consideration in the scheduling of many farming operations in both irrigated and dryland agriculture. Accurate predictions of bare soil evaporation can serve as the basis for decisions to increase the acreage planted with a given crop. An alternative is presented to previous approaches to bare soil evaporation estimation by empirically correlating the ratio of daily totals of actual to potential evaporation and the amplitude of the diurnal surface soil temperature wave. Since evaporation is directly related to the surface soil water pressure, the soil thermal inertia technique might be capable of prescribing relative bare soil evaporation rates which, combined with potential evaporation calculations, could allow determination of actual evaporation rates over the entire range of soil drying. Hydrology -- Arizona. Water resources development -- Arizona. Hydrology -- Southwestern states. Evaporation Transpiration Soil moisture Soil temperature Drying Lysimeters Soil types Loam Thermal properties Instrumentation Soil water Temperature Arizona Phoenix (Ariz)
199	Diurnal Trends in Water Status, Transpiration, and Photosynthesis of Saltcedar Williams, Mary Ellen, Anderson, Jay E. 16 April 1977 (has links) From the Proceedings of the 1977 Meetings of the Arizona Section - American Water Resources Assn. and the Hydrology Section - Arizona Academy of Science - April 15-16, 1977, Las Vegas, Nevada / Relative water content (RWC), water potential (P), and gas exchange were measured on saltcedar at the Bernardo, New Mexico, lysimeter site. RWC and s were closely correlated; but, water potential measurements, taken with a pressure bomb, were more convenient and reliable. RWC and r decreased sharply from sunup until about 0900, when minimum values of about -26 bars T or 80% RWC were reached. Water status then remained constant or improved slightly through late afternoon. Transpiration rates typically remained high until about noon and then began a steady, gradual decrease that continued throughout the afternoon. The data suggest that water stress may be a factor in initiating stomatal closure; however, transpiration continued to decline despite a constant or improved leaf water status. Maximum net photosynthetic rates occurred by 0900, and depressions throughout the remainder of the day were largely accounted for by increased leaf temperatures. Afternoon depressions in transpiration and photosynthesis occurred in twigs held at constant temperature and relative humidity, suggesting that a diurnal rhythm may be involved in control of gas exchange. Water status of plants growing on the lysimeters was comparable to that of plants in adjacent natural stands; gas exchange rates were slightly higher for the lysimeter-grown plants. Hydrology -- Arizona. Water resources development -- Arizona. Hydrology -- Southwestern states. Tamarisk Diurnal Consumptive use Water utilization Transpiration control Photosynthesis Moisture uptake Moisture deficit Pores Respiration Water loss Stomata Lysimeters Plant physiology
200	Tree transpiration inforest plantations: Effects of species, seasonality and diversity (Panama) / BAUMTRANSPIRATION IN FORSTLICHEN PLANTAGEN: EFFEKTE VON ARTEN, SAISONALITÄT UND DIVERSITÄT (PANAMA) Kunert, Norbert 09 June 2010 (has links) No description available. 580 Pflanzen (Botanik) Forest Sciences and Forest Ecology Baumtranspiration Biodiversität Monokultur Mischbestände Holzplantage Panama tree transpiration biodiversity monoculture mixtures tree plantation Panama 48.30 YQE 000: Physiologie {Forstbotanik} YQO 000: Ökologie {Forstbotanik}

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