Root Water Uptake and Soil Water Dynamics in a Karst Savanna on the Edwards Plateau, TX

Tokumoto, Ieyasu

03 October 2013

Woody plants are encroaching into a karst savanna on the Edwards Plateau in central Texas, but their impact on hydrology is unclear because of high variability in soil depth and uncertainties about shallow and deep root contributions to water uptake, and water dynamics in rocky soil. The overall objectives of this study are to quantify contributions of shallow and deep roots to water uptake, and to quantify the impact of rock on soil hydraulic properties and water storage. A study was conducted in a karst savanna with ~50% woody cover to monitor spatial and temporal variations in soil moisture and root water uptake with neutron probe and time-domain reflectometry measurements. Bulk density was measured using gamma densitometry. Measurements were made to a depth of 1.6 m in a 25 m  25 m grid (5 m node spacing). The results showed that rock created high spatial variability in water storage. Water storage capacity in the measurement grid ranged from 185 to 401 mm, and coupled with heterogeneous distribution of trees led to high spatial variability in root water uptake. Most of the water uptake came from the upper 1 m of the soil profile, but 10% came from below 1.6 m. This indicated that roots had access to water stored within the bedrock, possibly in soil pockets. Statistical analysis showed that spatial distribution of θ was significantly correlated with rock distribution in the profile. Laboratory evaporation measurements showed that Small volume fractions of rock can increase evaporation from soils by slowing upward movement of water, thereby maintaining capillary connectivity to the surface for a longer period of time. Two simulation models, van Genuchten (VG) and Durner, were compared with the data from evaporation experiments. Results showed that the Durner model was more appropriate than the VG model for describing water retention and hydraulic conductivity of rocky soils.

Invasive species

Root water uptake

Vadose zone processes affecting water table fluctuations: Conceptualization and modeling considerations

Shah, Nirjhar

01 June 2007

This dissertation focuses on a variety of vadose zone processes that impact water table fluctuations. The development of vadose zone process conceptualization has been limited due to both the lack of recognition of the importance of the vadose zone and the absence of suitable field data. Recent studies have, however, shown that vadose zone soil moisture dynamics, especially in shallow water table environments, can have a significant effect on processes such as infiltration, recharge to the water table, and evapotranspiration. This dissertation, hence, attempts to elucidate approaches for modeling vadose zone soil moisture dynamics. The ultimate objective is to predict different vertical and horizontal hydrological fluxes. The first part of the dissertation demonstrates a new methodology using soil moisture and water table data collected along a flow transect. The methodology was found to be successful in the estimation of hydrological fluxes such as evapotranspiration, infiltration, runoff, etc. The observed dataset was also used to verify an exponential model developed to quantify the ground water component of total evapotranspiration. This analysis was followed by a study which analyzed the impact of soil moisture variability in the vadose zone on water table fluctuations. It was found that antecedent soil moisture conditions in the vadose zone greatly affected the specific yield values, causing a broad range of water table fluctuations for similar boundary fluxes. Hence, use of a constant specific yield value can produce inaccurate results. Having gained insight into the process of evapotranspiration and specific yield, a threshold based model to determine evapotranspiration and subsequent water table fluctuation was conceptualized and validated. A discussion of plant root water uptake and its impact on vadose zone soil moisture dynamics is presented in the latter half of this dissertation. A methodology utilizing soil moisture and water table data to determine the root water uptake from different sections of roots is also described. It was found that, unlike traditional empirical root water uptake models, the uptake was not only proportional to the root fraction, but was also dependent on the ambient soil moisture conditions. A modeling framework based on root hydraulic characteristics is provided as well. Lastly, a preliminary analysis of observed data indicated that, under certain field conditions, air entrapment and air pressurization can significantly affect the observed water table values. A modeling technique must be developed to correct such observations.

Shallow water table

Evapotranspiration

Extinction depth

Root water uptake

Variable specific yield

American Studies

Arts and Humanities

Transpiração de plantas e condições hidráulicas do solo / Plant transpiration and soil hydraulic conditions

Casaroli, Derblai

19 May 2008

Taxas de transpiração inferiores às taxas potenciais limitam o crescimento e desenvolvimento vegetal e ocorrem em solos que apresentam condições hidráulicas inadequadas para a manutenção do fluxo de água requerido em direção às raízes de uma planta. A pesquisa que resultou nesta tese teve como objetivos: estimar em quais condições hidráulicas se inicia a redução da taxa de transpiração, em termos de potencial de fluxo matricial (Mcrit), teor de água ( ?crit), potencial matricial (hcrit) e condutividade hidráulica (Kcrit), para diferentes solos e condições atmosféricas; demonstrar experimentalmente que Mcrit é independente do tipo de solo e influenciado apenas pelas características radiculares e demanda atmosférica, ao contrário de ?crit, hcrit e Kcrit; comparar valores de Mcrit obtidos nos experimentos com respectivos valores de Mcrit estimados por um modelo de extração de água do solo por raízes, para uma mesma densidade radicular; propor uma alternativa para a estimativa de ?crit no solo, baseada na interrelação entre M, ? e h. O presente estudo conteve dois experimentos conduzidos em ambiente protegido, com plantas de feijão (Phaseolus vulgaris L.) cultivadas em vasos. O delineamento experimental utilizado, tanto no primeiro quanto no segundo experimento, foi o inteiramente casualizado com três repetições. Os tratamentos do primeiro experimento formaram uma combinação bifatorial 2x2 (solos: argiloso e arenoso; e regimes hídricos: sem e com deficiência hídrica) para as características das plantas e um fatorial (solos: argiloso e arenoso) para as condições hidráulicas críticas do solo. Para o segundo experimento os tratamentos tiveram uma combinação trifatorial 2x2x2 (solos: argiloso e arenoso; regimes hídricos: sem e com deficiência hídrica; e demandas atmosféricas: sem e com ventilação forçada) para as características das plantas e um bifatorial 2x2 (solos: argiloso e arenoso; e demandas atmosféricas: sem e com ventilação forçada) para as condições hidráulicas críticas. O ponto crítico (?crit, hcrit, Kcrit e Mcrit) foi identificado no dia anterior à transpiração relativa TR < 1. Compararam-se os valores de TR em função de ?, h, K e M observados no experimento (após o ponto crítico) com seus respectivos valores estimados por um modelo teórico, obtendo-se um bom ajuste. Verificaram-se diferenças na ordem de grandeza entre os valores de Mcrit observados no experimento em relação aos estimados por modelo (Mcrit*), em que Mcrit > Mcrit*. Em conseqüência disso, propôs-se uma alternativa para estimar as condições hidráulicas críticas para uma distribuição heterogênea da densidade radicular em frações de volume do solo. Os valores experimentais foram comparados aos obtidos pelo modelo, resultando nos índices RMSE (raiz do quadrado médio do erro), MAE (erro médio absoluto) e \"d\" (índice de concordância de Willmott). Os resultados evidenciaram que o Mcrit pode ser utilizado para identificar o início da taxa de transpiração decrescente e da diminuição na fotossíntese líquida, em plantas de feijão. Os valores de Mcrit podem ser transformados em ?crit e hcrit, que são mais facilmente medidos em campo. A heterogeneidade na distribuição do sistema radicular no solo infere em diferentes valores de Mcrit observados experimentalmente e obtidos por modelo. Pode-se estimar a TR com base nos valores de M (após o ponto crítico) para uma distribuição heterogênea das densidades radiculares em frações de volume do solo. O melhor ajuste ocorreu quando uma menor densidade radicular ocupasse uma maior fração de volume do solo (? 90%). / Transpiration lower than potential rates reduce plant productivity and occur in soils with hydraulic conditions that are inadequate to maintain the necessary water flux towards the plant roots. Soil physical models that describe root water uptake are an important tool to estimate this transpiration reduction. The research that resulted in this thesis aimed: to estimate under which hydraulic conditions occurs the onset of transpiration reduction in terms of matric flux potential (Mcrit), water content ( ?crit), pressure head (hcrit) and hydraulic conductivity (Kcrit) for different soil and atmospheric conditions; to demonstrate experimentally that Mcrit is independent of soil properties and only influenced by root characteristics and atmospheric demand, on the contrary of ?crit, hcrit e Kcrit; to compare values of Mcrit obtained in the experiments with Mcrit estimated by a root water uptake model at the same root length density; to estimate the onset of the falling rate phase from Mcrit values; to propose an alternative to estimate ?crit, based on the relationship among M, ? e h. The present study contained two greenhouse experiments with bean plants (Phaseolus vulgaris L.) in pots. A completely randomized design was used with three repetitions in both experiments. The treatments, in the first experiment, formed a factorial 2x2 combination (soils: loamy and sandy; and water regimes: irrigated and water deficit) for plant characteristics and a one-factorial was used for critical hydraulic conditions of the soil (soils: loamy and sandy). In the second experiment a 2x2x2 combination factorial was applied (soils: loamy and sandy; water regimes: irrigated and water deficit; and atmospheric demands: without and with forced ventilation) for plant characteristics and a 2x2 factorial (soils: loamy and sandy; and atmospheric demands: without and with forced ventilation) for the critical hydraulic conditions. The critical point (?crit, hcrit, Kcrit and Mcrit) was identified on the day previous to a relative transpiration TR <1. The TR values as a function of ?, h, K and M observed in the experiments (after occurrence of critical conditions) were compared with values estimated by a model, resulting in a good fit. The experimental values (Mcrit) and the model-estimated values (Mcrit*) were different, with Mcrit > Mcrit*. A model was proposed to estimate the critical hydraulic conditions by heterogeneous distribution of root densities in soil volume fractions. The experimental and model-estimated Mcrit were compared through the RMSE (root medium square error), MAE (medium absolute error) and \"d\" (agreement index of Willmott) indexes. The results showed that Mcrit can be used to identify the onset of the falling rate phase referring to transpiration and liquid photosynthesis for the bean crop. The Mcrit values can be transformed in ?crit and hcrit, which are easily measured at field. The heterogeneous distribution of the root system in the soil caused different values of Mcrit observed experimentally and Mcrit obtained by the model. A good estimation of TR was obtained through M values by using a heterogeneous distribution of root densities in the model. The best fit was obtained when a large soil volume fraction (? 90%) was modeled with a small root density and the remaining 10% with a high root density.

Critical hydraulic conditions

Falling rate transpiration

Feijão

Phaseolus vulgaris L.

Root water uptake

Sistema radicular

Solos - Propriedades físicas

Transpiração vegetal.

Transpiração de plantas e condições hidráulicas do solo / Plant transpiration and soil hydraulic conditions

Derblai Casaroli

19 May 2008

Taxas de transpiração inferiores às taxas potenciais limitam o crescimento e desenvolvimento vegetal e ocorrem em solos que apresentam condições hidráulicas inadequadas para a manutenção do fluxo de água requerido em direção às raízes de uma planta. A pesquisa que resultou nesta tese teve como objetivos: estimar em quais condições hidráulicas se inicia a redução da taxa de transpiração, em termos de potencial de fluxo matricial (Mcrit), teor de água ( ?crit), potencial matricial (hcrit) e condutividade hidráulica (Kcrit), para diferentes solos e condições atmosféricas; demonstrar experimentalmente que Mcrit é independente do tipo de solo e influenciado apenas pelas características radiculares e demanda atmosférica, ao contrário de ?crit, hcrit e Kcrit; comparar valores de Mcrit obtidos nos experimentos com respectivos valores de Mcrit estimados por um modelo de extração de água do solo por raízes, para uma mesma densidade radicular; propor uma alternativa para a estimativa de ?crit no solo, baseada na interrelação entre M, ? e h. O presente estudo conteve dois experimentos conduzidos em ambiente protegido, com plantas de feijão (Phaseolus vulgaris L.) cultivadas em vasos. O delineamento experimental utilizado, tanto no primeiro quanto no segundo experimento, foi o inteiramente casualizado com três repetições. Os tratamentos do primeiro experimento formaram uma combinação bifatorial 2x2 (solos: argiloso e arenoso; e regimes hídricos: sem e com deficiência hídrica) para as características das plantas e um fatorial (solos: argiloso e arenoso) para as condições hidráulicas críticas do solo. Para o segundo experimento os tratamentos tiveram uma combinação trifatorial 2x2x2 (solos: argiloso e arenoso; regimes hídricos: sem e com deficiência hídrica; e demandas atmosféricas: sem e com ventilação forçada) para as características das plantas e um bifatorial 2x2 (solos: argiloso e arenoso; e demandas atmosféricas: sem e com ventilação forçada) para as condições hidráulicas críticas. O ponto crítico (?crit, hcrit, Kcrit e Mcrit) foi identificado no dia anterior à transpiração relativa TR < 1. Compararam-se os valores de TR em função de ?, h, K e M observados no experimento (após o ponto crítico) com seus respectivos valores estimados por um modelo teórico, obtendo-se um bom ajuste. Verificaram-se diferenças na ordem de grandeza entre os valores de Mcrit observados no experimento em relação aos estimados por modelo (Mcrit*), em que Mcrit > Mcrit*. Em conseqüência disso, propôs-se uma alternativa para estimar as condições hidráulicas críticas para uma distribuição heterogênea da densidade radicular em frações de volume do solo. Os valores experimentais foram comparados aos obtidos pelo modelo, resultando nos índices RMSE (raiz do quadrado médio do erro), MAE (erro médio absoluto) e \"d\" (índice de concordância de Willmott). Os resultados evidenciaram que o Mcrit pode ser utilizado para identificar o início da taxa de transpiração decrescente e da diminuição na fotossíntese líquida, em plantas de feijão. Os valores de Mcrit podem ser transformados em ?crit e hcrit, que são mais facilmente medidos em campo. A heterogeneidade na distribuição do sistema radicular no solo infere em diferentes valores de Mcrit observados experimentalmente e obtidos por modelo. Pode-se estimar a TR com base nos valores de M (após o ponto crítico) para uma distribuição heterogênea das densidades radiculares em frações de volume do solo. O melhor ajuste ocorreu quando uma menor densidade radicular ocupasse uma maior fração de volume do solo (? 90%). / Transpiration lower than potential rates reduce plant productivity and occur in soils with hydraulic conditions that are inadequate to maintain the necessary water flux towards the plant roots. Soil physical models that describe root water uptake are an important tool to estimate this transpiration reduction. The research that resulted in this thesis aimed: to estimate under which hydraulic conditions occurs the onset of transpiration reduction in terms of matric flux potential (Mcrit), water content ( ?crit), pressure head (hcrit) and hydraulic conductivity (Kcrit) for different soil and atmospheric conditions; to demonstrate experimentally that Mcrit is independent of soil properties and only influenced by root characteristics and atmospheric demand, on the contrary of ?crit, hcrit e Kcrit; to compare values of Mcrit obtained in the experiments with Mcrit estimated by a root water uptake model at the same root length density; to estimate the onset of the falling rate phase from Mcrit values; to propose an alternative to estimate ?crit, based on the relationship among M, ? e h. The present study contained two greenhouse experiments with bean plants (Phaseolus vulgaris L.) in pots. A completely randomized design was used with three repetitions in both experiments. The treatments, in the first experiment, formed a factorial 2x2 combination (soils: loamy and sandy; and water regimes: irrigated and water deficit) for plant characteristics and a one-factorial was used for critical hydraulic conditions of the soil (soils: loamy and sandy). In the second experiment a 2x2x2 combination factorial was applied (soils: loamy and sandy; water regimes: irrigated and water deficit; and atmospheric demands: without and with forced ventilation) for plant characteristics and a 2x2 factorial (soils: loamy and sandy; and atmospheric demands: without and with forced ventilation) for the critical hydraulic conditions. The critical point (?crit, hcrit, Kcrit and Mcrit) was identified on the day previous to a relative transpiration TR <1. The TR values as a function of ?, h, K and M observed in the experiments (after occurrence of critical conditions) were compared with values estimated by a model, resulting in a good fit. The experimental values (Mcrit) and the model-estimated values (Mcrit*) were different, with Mcrit > Mcrit*. A model was proposed to estimate the critical hydraulic conditions by heterogeneous distribution of root densities in soil volume fractions. The experimental and model-estimated Mcrit were compared through the RMSE (root medium square error), MAE (medium absolute error) and \"d\" (agreement index of Willmott) indexes. The results showed that Mcrit can be used to identify the onset of the falling rate phase referring to transpiration and liquid photosynthesis for the bean crop. The Mcrit values can be transformed in ?crit and hcrit, which are easily measured at field. The heterogeneous distribution of the root system in the soil caused different values of Mcrit observed experimentally and Mcrit obtained by the model. A good estimation of TR was obtained through M values by using a heterogeneous distribution of root densities in the model. The best fit was obtained when a large soil volume fraction (? 90%) was modeled with a small root density and the remaining 10% with a high root density.

Feijão

Sistema radicular

Solos - Propriedades físicas

Transpiração vegetal.

Critical hydraulic conditions

Falling rate transpiration

Phaseolus vulgaris L.

Root water uptake

Water dynamics in the rhizosphere / How mucilage affects water flow in soils

Kröner, Eva

10 February 2016

Die Wurzelwasseraufnahme aus dem Boden wird durch die Rhizosphäre beeinflusst. Die Rhizosphäre ist eine dünne Bodenschicht, die sich um Wurzeln herum bildet. Die Rhizosphäre wird durch Mucilage beeinflusst. Mucilage ist ein polymeres Gel, was von Wurzeln abgesondert wird und vor allem die hydraulischen Eigenschaften der Rhizosphäre verändert. Wenn es im Kontakt mit Wasser ist, kann Mucilage große Mengen an Wasser aufnehmen, aber wenn es trocken ist, wird seine Oberfläche hydrophob. Hier konzentrieren wir uns auf den Effekt von Mucilage auf die hydraulischen Eigenschaften des Bodens. Zunächst präsentieren wir experimentelle und numerische Studien, die die hydraulischen Prozesse in der Rhizosphäre nach der Bewässerung von trockenem Boden beschreiben. Bei Mucilagekonzentrationen, die niedriger als ein gewisser Schwellwert waren, konnte Wasser durch die Rhizosphärenschicht fließen, über dieser Konzentration wurde die Schicht wasserundurchlässig während der ersten Minuten bis zu Stunden nach Bewässerung. Wir präsentieren eine analytische Abschätzung der Mucilagekonzentration an der Perkolationsschwelle als Funktion von mittlerer Teilchengröße und Bodenwasserpotential nach Bewässerung. Die Abschätzung wurde an Hand von Experimenten des kapillaren Aufstiegs in Bodensäulen validiert. Wir entwickelten ein effektives Model um zu beschreiben, wir Mucilage die hydraulischen Funktionen des Bodens verändert: (a) Quell- und Trocknungsprozesse von Mucilage resultieren in Nicht-Gleichgewichtsdynamiken zwischen Wassergehalt und Wasserpotential, (b) die Präsenz von Mucilage im Boden reduziert das Wasserpotential bei einem gegebenen Wassergehalt und (c) Mucilage ist viskos und reduziert dadurch die hydraulische Leitfähigkeit des Bodens bei einem gegebenen Wassergehalt. In Experimenten mit Boden-Mucilage-Mischungen testeten wir das Model und wandten es an, um Beobachtungen von früheren Experimenten mit echten Pflanzen zu simulieren, die veränderte hydraulische Dynamiken in der Rhizophäre zeigen. Im Anhang dieser Arbeit sind zwei Studien zur Wärmeausbreitung von Erdkabeln. Hier können hydraulische Dynamiken autreten, die dem radialen Wasserfluss zu einer einzelnen Wurzel ähneln.

630

Root water uptake

Heat dissipation from underground cables

Coupled water, vapour and heat flow

Hydraulic dynamics in the rhizosphere

Land- und Forstwirtschaft (PPN621302791)

Etude de l’alimentation hydrique du palmier dattier (Phoenix dactylifera L.) dans le contexte pédoclimatique de la zone littorale de la République de Djibouti / Study of the date palm (Phoenix dactylifera L.) water uptake in the coastal pedoclimatic context of the Republic of Djibouti

Said Ahmed, Hami

09 April 2015

Le palmier-dattier constitue une des rares cultures à vocation alimentaire adaptées aux conditions climatiques extrêmes (sécheresse, salinité), telles que rencontrées à Djibouti. Dans un contexte de ressources en eau fortement limitées, la connaissance des modalités de l’alimentation hydrique du palmier dattier est essentielle. L’objectif de ce travail de recherche est d’acquérir cette connaissance, dans le contexte pédoclimatique de Djibouti, par la réalisation d’un suivi in situ du fonctionnement hydrique du système sol-palmier, à l’échelle d’un individu, et la quantification du puits racinaire du palmier-dattier. Un palmier-dattier, pleinement développé, a été instrumenté à l’échelle de la cuvette d’irrigation, à l’aide de plusieurs tubes d’accès de sonde à neutrons, pour le suivi de la teneur en eau volumique du sol, et de plusieurs tensiomètres, répartis de 10 à 160 cm de profondeur. Trois expériences d’infiltration/redistribution a été réalisées successivement, la première sans altérer le fonctionnement du système sol-palmier, la seconde après avoir coupé le palmier, tout en permettant l’évaporation de la surface du sol, la dernière après avoir couvert la surface du sol afin d’empêcher l’évaporation. Les résultats mettent en évidence une forte hétérogénéité des propriétés hydriques du sol, avec une stratification liée au contexte sédimentaire littoral. L’impact du puits racinaire sur la dynamique hydrique du sol est observé jusqu’à 80 cm de profondeur. Pour la période fraîche, les besoins en eau du palmier dattier sont estimés à 130 L par jour, avec une fréquence d’irrigation d’une fois toutes les 2 semaines. Pour la première fois, le coefficient cultural du palmier dattier (kc = 1,39) a été établi dans les conditions climatiques de Djibouti. Les résultats obtenus contribueront à une meilleure gestion de l’irrigation et à une meilleure maîtrise du risque de salinisation du sol dans le contexte pédoclimatique de la République de Djibouti. / Date palm is one of the few food crops adapted to the extreme weather conditions (drought, salinity), such as encountered in Djibouti. In the context of highly limited water resources, knowledge of the date palm water requirements is essential. The objective of this research was to determine the date palm water requirements, in the Djibouti pedoclimatic context, using in situ monitoring of water transport in the soil-plantatmosphere system, at the scale of a single date palm tree, and to quantify the date palm root water uptake. A fully developed date palm tree was instrumented at the irrigation basin scale, using several access tubes for neutron probe for monitoring the soil volumetric water content, and several tensiometers, installed from 10 to 160 cm depth. Three infiltration/redistribution experiments have been performed successively, the first without alteration of the soil-plant system, the second after cutting off a date palm tree while allowing the surface evaporation, the last with covering the soil surface to avoid evaporation. The results show large heterogeneity in soil hydraulic properties, with stratification linked to the coastline sedimentary context. The root water uptake is observed up to 80 cm depth. The date palm water requirements in the fresh period are estimated at 130 liters per day with a frequency of irrigation of one time every two weeks. For the first time, the date palm cultural coefficient has been established in the Djibouti climatic conditions (kc = 1.39). The obtained results will contribute to better management of irrigation and to improve the control of soil salinization in the pedoclimatic context of the Republic of Djibouti.

Palmier dattier

Sol

Puits racinaire

Climat semi-désertique

Evaporation

Transpiration

Transferts hydriques

Date palm

Soil

Root water uptake

Semi-desert climate

Evaporation

Transpiration

Water transfer

631.432

Quantitative imaging of water flow in soil and roots using neutron radiography and deuterated water

Zarebanadkouki, Mohsen

08 May 2013

Wo und wie schnell nehmen Wurzeln Wasser auf? Obwohl diese Frage in Pflanzen- und  Bodenwissenschaften von großer Bedeutung ist, gibt es nur wenige experimentelle Daten darüber, an welcher Stelle der Wurzeln eine transpirierende Pflanze das Wasser aus dem Boden erhält. Die Antwort auf diese Frage erfordert direkte und in-situ Messungen des lokalen Wasserflusses in die Wurzel hinein. Ziel dieser Arbeit war es, eine neue Methode zu entwickeln und anzuwenden, um den lokalen Wasserfluss in unterschiedliche Segmente der Pflanzenwurzeln zu quantifizieren. Dabei wurde Neutronenradiographie eingesetzt um den Transport von deuteriertem Wasser (D2O) in die Wurzel von Lupinen zu untersuchen. Die Lupinen wuchsen in Aluminium Containern, die mit sandigem Boden gefüllt waren. Der sandige Boden wurde mit Hilfe von 1cm-dicken Schichten groben Sandes in verschiedene Bereiche eingeteilt. Diese Schichten reduzierten die Diffusion von D2O zwischen den verschiedenen Bereichen.  D2O wurde in ausgewählte Bereiche tagsüber (transpiriende Pflanzen) und nachts (nicht transpiriernde Pflanze) injiziert. Transport von D2O in die Wurzeln hinein wurde durch Neutronenradiographie mit einer räumlichen Auflösung von 100 µm in Intervallen von 10 Sekunden aufgezeichnet. Die Messungen zeigten: i) Transport von D2O in die Wurzel hinein war tagsüber schneller als nachst; ii) D2O wurde tagsüber schnell entlang der Wurzel in Richtung Spross transportiert, während dieser axiale Fluss nachts vernachlässigbar war. Die Unterschiede zwischen Tag- und Nachtmessungen wurden durch konvektiven Transport von D2O in den Wurzeln erklärt. Um den effektiven Wasserfluss in die Wurzeln hinein zu quantifizieren, wurde ein einfaches Konvektions-Diffusions Modell entwickelt, wobei die Zunahme der D2O Konzentration in Wurzeln vom konvektiven Transport abhängt und von the Diffusion des D2O in die Wurzeln. Die Ergebnisse zeigten, dass die Wasseraufnahme nicht gleichmäßig entlang der Wurzel stattfindet. Die Wasseraufnahme war in den oberen Bodenschichten höher als in den tieferen. Entlang einzelner Wurzeln war der radiale Fluss in nahen Teilen der Wurzel höher als in den weiter entfernten Teilen der Wurzel. In Lupinen fand die Wasseraufnahme im Wesentlichen in den lateralen Wurzeln statt. Die Funktion der Pfahlwurzel war es, das Wasser der lateralen Wurzeln zu sammeln und zum Spross zu transportieren. Diese Funktion wird durch eine geringe radiale und eine hohe axiale Leitfähigkeit sichergestellt.  Wir haben diese Technik auch angewandt um den Einfluss der Rhizosphäre auf die Wasseraufnahme zu untersuchen. Wie vor Kurzem auch in der Literatur berichtet wurde, wurde auch in dieser Arbeit beobachtet, dass der Boden in der unmittelbaren Nähe der Wurzeln, der sogenannten Rhizosphäre, hydrophob wird, wenn der Boden trocken wird. Zum ersten Mal konnte gezeigt werden, dass durch die Hydrophobizität der Rhizosphäre die Wasseraufnahme nach Trocknung und folgender Bewässerung reduziert wird. Es wurde die Schlussfolgerung gezogen, dass nach Trocknung die Rhizosphäre einen entscheidenden Wiederstand für den Wasserfluss zur Wurzel darstellt. Das beeinflusst vermutlich auch die Ausdehnung des Bereiches der Wurzeln, in dem Wasser aufgenommen wird. Die Bedeutung dieser Arbeit ist die Entwicklung einer neuen Methode, um Wasseraufnahme durch Wurzeln lebender Pflanzen lokal zu quantifizieren. Diese Methode macht es möglich quantitativ zu messen, wo und wie schnell Wurzeln Wasser im Boden aufnehmen. Diese Technik wird es erleichtern, die Funktionsweise der Wurzeln verschiedener Pflanzen zu verstehen und den Einfluss von Wurzelwachstum und wechselnder äußerer Bedingungen, wie Wassergehalt, Transpiration und Verfügbarkeit von Nährstoffen und vieler weiterer Faktoren zu untersuchen.  Die Antwort auf diese Fragen könnten einen weiten Bereich für landwirtschaftliche Anwendungen eröffnen, die darauf abzielen, Bewässerungsmethoden zu verbessern.

630

Root water uptake

Neutron radiography

Rhizosphere

Hydrophobicity

Radial flux

Axial flux

Root hydraulic conductivity

Lupine

Deuterated water

Land- und Forstwirtschaft (PPN621302791)

Contaminant fate and transport analysis in soil-plant systems

Goktas, Recep Kaya

20 January 2011

The main objective of this study is to develop a modeling methodology that facilitates incorporating the plant pathway into environmental contamination models recognizing the fact that plants are dynamic entities that regulate their life cycle according to natural and anthropogenic environmental conditions. A modeling framework that incorporates the plant pathway into an integrated water flow and contaminant transport model in terrestrial systems is developed. The modeling framework is aimed to provide a tool to analyze the plant pathway of exposure to contaminants. The model developed using this framework describes the temporal and spatial variation of the contaminant concentration within the plant as it is interacting with the soil and the atmosphere. The first part of the study focuses on the integration of the dynamics of water and contaminant distribution and plant related processes within the vadose zone. A soil-plant system model is developed by coupling soil-water flow, contaminant transport, plant life-cycle, and plant pathway models. The outcome unifies single media continuous models with multimedia compartmental models in a flexible framework. The coupling of the models was established at multiple interfaces and at different levels of solution steps (i.e. model development phase vs. numerical solution phase). In the second part of the study, the soil-plant system model is extended to cover large spatial areas by describing the environmental system as a collection of soil-plant systems connected through overland flow and transport processes on the ground surface and through lateral interactions in the subsurface. An overland flow model is integrated with the previously coupled model of unsaturated zone soil-water flow and plant life-cycle by solving the flow model equations simultaneously within a single global matrix structure. An overland / subsurface interaction algorithm is developed to handle the ground surface conditions. The simultaneous solution, single-matrix approach is also adopted when integrating the overland transport model with the previously coupled models of vadose zone transport and plant pathway. The model developed is applied to various environmental contamination scenarios where the effect of the presence of plants on the contaminant migration within environmental systems is investigated.

Plant pathway

Contaminant fate

Contaminant transport

Vadose zone

Plant's contamination

Overland flow modeling

Plant growth modeling

Coupled environmental systems

Irrigation

Soil-plant system

Integrated modeling

Root water uptake

Multimedia environmental modeling

Plants, Effect of xenobiotics on

Plant growing media Contamination

Mathematical models