Métodos para Medir la Humedad del Suelo para la Programación del Riego ¿Cuándo?

Martin, Edward C., Munoz, Carolina

02 1900

8 pp. / Reviewed 2/2017; Originally Published 2000 / El manejo apropiado del riego requiere la evaluación de parte del agricultor de sus necesidades de riego en base a medidas de varios parámetros físicos del suelo. Algunos productores utilizan equipo sofisticado mientras que otros se basan en métodos empíricos o en el sentido común. Cualquiera que sea el método usado, cada uno tiene sus propios méritos y limitaciones. El agricultor generalmente se hace dos preguntas al desarrollar una estrategia para el manejo del riego: “¿Cuándo regar?” y “¿Cuánta agua aplicar?”. Este boletín responde a la pregunta CUÁNDO. Reviewed 2/2017; Originally Published 09/2010.

evaporation

Capacidad de campo

Capacidad de campo

Plant available water

Subsoil constraints to root growth and water use efficiency in northern grain soils: osmotic and toxic effects of salinity

Anna Sheldon

Unknown Date

Abstract Salinity has considerable adverse effects on agriculture through reduction in plant growth and water use. Sodium chloride salinity has both an osmotic effect on plant water relations, and a toxic effect on cellular processes. The relative contribution of these two effects to plant growth depends on a range of factors including plant specific tolerance mechanisms, such as Na and Cl exclusion, compartmentation of ions at a whole plant and cellular level, and synthesis of organic osmotic compounds for plant osmotic adjustment. Plants growing in saline soil would also experience reduced plant available water, due to the additional osmotic effect on soil water potential. The effect of salinity on plant growth is further complicated by the interactions of environmental conditions with plant water and ion uptake. This thesis examines the osmotic and toxic effects of salinity on wheat (Triticum aestivum L.) and chickpea (Cicer arietinum L.), with particular focus on plant water availability, effects of Na and Cl toxicity, and temperature and humidity effects. While considerable research has been undertaken into the physiological response of plants to NaCl, our understanding of the capacity of plants to extract water from saline soils has remained largely theoretical. Total plant available water is largely determined by the matric potential of the soil. Presence of sodium chloride would have an additional osmotic effect, and previous theory stated that the salt tolerance of the plant determined the extent to which this osmotic potential reduced plant available water. The capacity of wheat and chickpea to extract water from saline soils was examined in a soil experiment where water stress was imposed on established plants, which were then grown until permanent wilting point (PWP) was reached. Wheat extracted to lower soil water potentials (-1.5 MPa), than chickpea (-900 kPa) in 0 NaCl treatments. Where salinity was low to moderate, plants were able to extract water to a PWP determined by the combined total of matric and osmotic potentials. Wheat extracted water to PWP in salinity treatments up to soil ECse of 5.3 dS/m, and chickpea to 2.9 dS/m. As salinity increased, toxic effects of salinity dominated, and water extraction by plants was significantly lower than that determined by total soil water potential. Solution culture experiments investigated the comparative toxic effects of Na, Cl and salt mixtures. Growth of wheat was reduced by Na toxicity, but not Cl toxicity, with Na causing a small, but significant additional reduction in growth, compared to high Cl or a salt mixture. Reductions in growth of 50% from control treatments occurred at -500 kPa for the Na treatment, and -630 kPa for the Cl and mixed salt treatments. In contrast, growth of chickpea was significantly reduced by both Na and Cl toxicity, with a large difference in growth compared to the salt mixture. Growth reductions of 50% occurred at -330 kPa for the Cl treatments, and -450 kPa for the Na treatment. A 50% growth reduction was not observed in the mixed salt treatment. Tolerance of saline conditions is reduced under stressful environmental conditions, such as high temperature and low relative humidity. Hot and dry conditions were shown to reduce the tolerance of saline conditions by both wheat and chickpea, compared to cool or humid conditions. Tissue concentrations of Na in wheat were disproportionately high in treatments with high evaporative demand, while tissue Cl was not related to evaporative demand. Tissue concentrations of Na in chickpea increased with temperature, but not relative humidity, while tissue Cl concentrations were highly correlated with evaporative demand. The relationships between NaCl salinity, plant water use, and environmental conditions were examined, allowing further development of the two phase salinity model. In particular, the transition point between the osmotic and toxic salinity effects. While the concentration of NaCl in the soil remains the primary factor, soil water status, environmental stresses and presence of other salts may dictate whether salinity be tolerated by the plant or not. The ability of the plant to extract water to PWP, as determined by total matric and osmotic potential has been identified as a useful indicator of salinity tolerance. The point at which toxicity of Na and/or Cl is observed is associated with a rapid increase in Na and Cl uptake by the shoot tissue, and a decrease in the amount of water the plant is able to extract from the soil. Within the osmotic region of salinity stress, the plant is able to extract water to PWP, but as NaCl becomes toxic the plant is unable to utilize this water.

Wheat

Chickpea

Salinity

Sodium

Chloride

Toxicity

plant available water

Osmotic Stress

Zur Bedeutung der Bodenstruktur für den Ertrag von Zuckerrüben / eine pflanzenbauliche und ökonomische Analyse in einer Zuckerrüben - Getreide - Fruchtfolge mit dauerhaft differenzierter Bodenbearbeitung / Relevance of soil structure for sugar beet yield / - an agronomical and economical analysis in a sugar beet - winter wheat rotation with long term variable cultivation tillage systems

Dieckmann, Jan

23 January 2008

No description available.

630 Landwirtschaft

Veterinärmedizin

Agricultural Sciences

Zuckerrübe

Konservierende Bodenbearbeitung

Eindringwiderstand

Lagerungsdichte

Luftkapazität

nutzbare Feldkapazität

Nährstoffe

P

K

Mg

Corg

Nt

Corg/Nt Verhältnis

Sugar beet

conservation tillage

direct drilling

plant density

soil structure

penetration resistance

dry bulk density

air filled pore volume

plant available water content

nutrients

P

K

Mg

Corg

Nt

Corg/Nt-ratio

48.36 Bodenbearbeitung

Retenção e disponibilidade de água em solos de Santa Catarina: avaliação e geração de funções de pedotransferência / Water retention and availability in soils of Santa Catarina: Evaluation and generation of pedotransfer functions

Costa, André da

24 February 2012

Made available in DSpace on 2016-12-08T15:50:03Z (GMT). No. of bitstreams: 1 PGMS12DA009.pdf: 7314998 bytes, checksum: 8e93659478a7813ba0b934959e229681 (MD5) Previous issue date: 2012-02-24 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Studies on the retention and availability of water are scarce for humid subtropical and temperate regions in the Southern Hemisphere. The objectives of this study were to evaluate, generate and validate some pedotransfer functions (PTFs) to estimate the retention and the availability of water in soils of Santa Catarina. Were sampled 44 profiles, in areas under different vegetal coverings, to determine the water retention at suctions from zero to 1.500 kPa, the particles size distribution (7 classes), the organic matter content, the bulck density and particle density of soil, the conductivity hydraulic, and the aggregate stability. Regarding the attributes, soils with finer texture and / or more organic matter retain higher water content, where the organic matter is the main attribute that governs the availability of water, mainly in the surface horizons. Some classes of sand, mainly very fine sand, fine and coarse fractions, have greater effects on water availability than the silt fraction. The soils with contrasting textural classes, with high contents of clay or sand, have the same content of water available, although the sand soils have very low field capacity. Increased water availability occurs in soils with textural class loam, with higher content of organic matter and the lower availability occurs in sand class soils. In relation to lithology, there is a higher retention in soils derived from igneous extrusive rocks of the Serra Geral Formation, metamorphic, intrusive igneous, and sedimentary with fine texture, and a lower retention in those derived from rocks or sedimentary deposits rich in quartz. Increased availability of water occurs in soils derived from siltstone and less in soils derived from granite and recent alluvial deposits. Regarding soil classes (suborders), the water retention is higher in Cambisols, Ferralsols and Nitosols, and lower in Quartzarenic Neosols. In relation the regions, the soils of the Midwest and West, Serrano Highlands and Valley of Itajaí have high water retention, the intermediary are the Eastern Sierra, and lower in the coast. Humic Cambisols and Entisols, located in the Serrano Highlands has increased availability of water, mainly because of high contents of organic matter. In relation to soil types in the normative instruction n. 2/2008 of the MAPA (BRAZIL, 2008), which classifies the soils as a function of clay and sand, it is observed that is not adequate to classify the soils of Santa Catarina in terms of availability of water, although, the hydraulic conductivity of the unsaturated soil is lower in Type 1 soils. In relation the pedotransfer functions of literature, they better estimate the retention than water availability and with greater precision by the functions originated from climate regions subtropical and for the subsurface horizons of the soil. Most functions evaluated underestimates the water retention, with greater deviations in soils with 20-60 % clay. About the functions generated for the soils of Santa Catarina, the estimation of retention and availability of water was better in those adjusted separately for surface and subsurface horizons. To estimate the water retention, the point PTFs must be used including data of the texture, organic matter and their interactions. To estimate the availability, the point PTFs should include the five classes of sand, silt, clay, organic matter, soil bulk density, soil particles density, total porosity and their interactions. The parametrics PTFs estimate properly the water retention curve for most of the textural classes of the soil, when data of texture, organic matter, soil bulk density, soil particles density, total porosity and their interactions are included as predictors. The class PTFs estimate properly the water retention curve for most of the soil textural classes of Santa Catarina / Estudos sobre a retenção e disponibilidade de água são escassos para as regiões de clima subtropical ou temperado úmido do hemisfério sul. Os objetivos deste estudo foram avaliar, gerar e validar funções de pedotransferência (FPTs) para estimar a retenção e a disponibilidade de água em solos de Santa Catarina. Foram amostrados 44 perfis, em áreas sob diferentes coberturas vegetais, para determinar a retenção de água nas sucções de zero até 1.500 kPa, a distribuição do tamanho de partículas (7 classes), o teor de matéria orgânica, a densidade do solo e de partículas, a condutividade hidráulica e a estabilidade de agregados. Em relação aos atributos, solos com textura mais fina e/ou com maior teor de MO retêm maior conteúdo de água, sendo a MO é o principal atributo que governa a disponibilidade de água, principalmente nos horizontes superficiais. Algumas classes de areia, principalmente as areias muito fina, fina e grossa, possuem maiores efeitos sobre disponibilidade de água do que a fração silte. Os solos com classes texturais contrastantes, com elevados teores de argila ou de areia, disponibilizam o mesmo conteúdo de água disponível, embora os arenosos tenham baixa capacidade de campo. Maior conteúdo de água disponível ocorre em solos das classes com textura franca e com maior teor de MO, enquanto que a menor disponibilidade ocorre em solos da classe areia. Em relação à litologia, ocorre uma maior retenção em solos derivados de rochas ígneas extrusivas da Formação Serra Geral, e de rochas metamórficas, ígneas intrusivas e sedimentares de textura fina, e menor nos derivados de rochas ou depósitos sedimentares ricos em quartzo. Maior disponibilidade de água ocorre em solos derivados de siltitos e o menor em solos derivados de granito e de depósitos aluvionares recentes. Em relação às classes de solos (subordens), a retenção de água é maior nos Cambissolos, Nitossolos e Latossolos e menor nos Neossolos Quartzarênicos. Em relação às regiões, os solos do Meio Oeste e Oeste, Planalto Serrano e Vale do Itajaí possuem elevada retenção de água, euquanto que, nos da Serra Leste é intermediária e os do Litoral é baixa. Os Cambissolos Húmicos e os Neossolos Litólicos, localizados no Planalto Serrano, têm maior disponibilidade de água, principalmente devido aos elevados teores de matéria orgânica. Em relação aos tipos de solos da instrução normativa n. 2/2008 do MAPA (BRASIL, 2008), que classifica os solos em função do teor de argila e areia, observa-se que a mesma não é adequada para classificar os solos catarinenses quanto a disponibilidade de água. Entretanto, a condutividade hidráulica não saturada é menor nos solos do Tipo 1. Em relação às funções de pedotransferência (FPTs) publicadas na literatura, elas estimam melhor a retenção do que a disponibilidade de água, com maior precisão pelas funções originadas de regiões de clima subtropical e para os horizontes subsuperficiais do solo. A maioria das funções avaliadas subestima a retenção de água, com erros maiores nos solos com 20 a 60% de argila. Quanto às funções geradas para os solos de Santa Catarina, as que melhor estimam a retenção e disponibilidade de água são aquelas ajustadas separadamente para os horizontes superficiais e subsuperficiais. Para estimar a retenção de água devem ser utilizadas as FPTs pontuais que incluem dados de textura, matéria orgânica do solo e suas interações. Para estimar a disponibilidade de água devem ser utilizadas as FPTs pontuais que utilizam as cinco classes de areia, silte, argila, matéria orgânica, densidade do solo e de partículas, porosidade total e suas interações. As FPTs paramétricas estimam adequadamente a curva de retenção de umidade do solo para a maioria das classes texturais, quando são incluídos dados de textura, matéria orgânica, densidade do solo e de partículas, porosidade total e suas interações como variáveis preditoras. As FPTs de classe estimam adequadamente a curva de retenção de água do solo para a maioria das classes texturais dos solos de Santa Catarina

capacidade de campo

ponto de murcha permanente

disponibilidade de água às plantas

pedofunções

curva de retenção de água no solo

análise de trilha

análise de regressão múltipla

field capacity

permanent wilting point

plant available water

pedofunctions

water retention curve

path analysis

muliple regression analysis

CNPQ::CIENCIAS AGRARIAS::AGRONOMIA

Cinétique d'évolution structurale des sols argileux : relation stress hydrique-stress salin ; Application à la biodiversité et rendement de culture / Kinetics of structural evolution of clay dominated soils : water stress-salt stress relationship; biodiversity and crop yield application

Radimy, Raymond Tojo

11 December 2015

Les marais de l'Ouest ont été gagnés sur les sédiments fluvio-marins par poldérisation débutée dès le moyen âge. Les aménagements hydrauliques avaient, initialement, des objectifs sanitaires et d'élevage. A partir des endiguements, ils ont divisé les territoires en marais mouillés et marais desséchés. Depuis les années 1970 le développement des cultures intensives de céréales a nécessité un rabaissement complémentaire de la nappe par drainage en partie pour augmenter la désalinisation de surface et limiter l’engorgement des sols. Néanmoins, ces territoires restent caractérisés par des nappes proches de la surface. En conséquence les profils hydriques vont être gouvernés par les conditions météorologiques y compris l'évapotranspiration, la pluviométrie, mais également par les remontées capillaires issues d'une nappe salée. D'autre par la nature argileuse des sols et ses propriétés de retrait conditionnent énormément le fonctionnement hydrodynamique et les évolutions de structure.La première partie du travail a été de suivre les évolutions des profils hydriques et de salinité en parcelles non drainées (prairies) et en parcelles drainées (Maïs, Blé, Tournesol). Ces suivis ont été complétés par les mesures des niveaux de nappes et par des mesures tensiométriques via des bougies poreuses implantées à différentes profondeurs. L'objectif final a été de calculer et modéliser les profils de réserve utile (RU) et de RU "résiduelle" utilisable par les plantes. Dans ces systèmes alimentés par les remontées capillaires, le réseau racinaire puise l'eau dans la zone non saturée de surface (vadose) puis dans la zone saturée sous-jacente. La teneur en eau caractéristique de l'interface zone non saturée - zone saturée a été déterminée par analogie entre les chemins d'état de la matrice argileuse le long de sa courbe de retrait et du sol le long de sa courbe de compaction. Les profils de RU résiduelle utilisable par les plantes ont été calculés à partir des profils de teneurs en eau puis comparés aux profils de RU obtenus via les données de station météorologique. Ces profils de RU résiduelle ont pu être écrits sous forme d'équation polynomiale du second degré puis modélisés. Dans cet environnement alimenté par les remontées capillaires, ces profils de RU résiduelles peuvent être modélisés à partir d'un paramètre facilement mesurable en surface qui prend en compte la structure du sol et les conditions météorologique : soit la teneur en eau à 10 cm de profondeur. Cette modélisation reste suffisamment réaliste pour être utilisée comme un outil prédictif face à la pédodiversité et/ou les rendements de culture.A ce travail s'ajoute deux études préliminaires : - les mesures des conductivités thermiques effectives de ces sols par la méthode du fil chaud et leurs modélisations dans les systèmes biphasés : eau - argile et air - argile, mais également pour les systèmes triphasés non saturés : eau - air - argile. Les perspectives sont la modélisation des transferts thermiques et hydriques dans le sol à partir de la surface, - et l'élaboration d'un protocole d'imprégnation-polymérisation des sols argileux humides par des résines de type HEMA. Cette imprégnation permet d'envisager la confection de lames minces dans le matériau argileux induré avec conservation de sa structure initiale humide. Les perspectives sont la pétrographie quantitative à l'interface racine - sol le long de profils verticaux dans les environnements argileux à degrés de saturation et structure évolutives. / The coastal marshlands are territories generally reclaimed on primary fluvio-marine sediments. They result from hydraulic managements and/or polderization which may date from the Middle Ages. Historically these hydraulic managements were built for goals of wholesomeness, breeding and farming. They isolate two territories: the dried marshes and the wet marshes. For the intensive cereal crops the slow drying caused by land reclamation was recently improved by the drainage, in part for increase the depth of desalinization and decrease waterlogging. Nevertheless, these territories remain characterized by shallow ground water of initial salt water. Consequently, the hydric profiles are governed by the meteoric conditions including the Evapotranspiration, the rainfall, but also the capillarity rises from the salt groundwater. Moreover, the clay dominated nature of the soils and their drastic shrinkage properties govern the hydrodynamic functioning and the soil structure behavior.The first part of the work was the monitoring of the water content and salinity profiles in drained cereal crops and in undrained grasslands. These measurements have been completed by the ground water level and tensiometric monitoring. The final goal was the calculation and modeling of the available water capacity (AWC) and plant available water (PAW) profiles. In these systems mainly supplied by the capillarity rises, the root network gets water in the subsurface vadose zone and then in the deeper saturated groundwater zone. The water content characteristic of the interface between the vadose and saturated zone was determined by comparison between the clay material state paths along its shrinkage curve and along its compaction curve. The PAW profiles were calculated from the water content profiles and then compared to the AWC profiles. The PAW profiles have been equated as polynomial second degree equations. In these shallow groundwater environments the PAW profiles have been modeled taking into account an easy measurable surface parameter which includes the soil structure behavior and the meteoric conditions: i.e. the water content measured at 10 cm depth. The PAW modelling remains sufficiently realistic to be used as a tool for farming management. Two preliminary studies were added to this work: - the measurement of effective thermal conductivity of the clayey soils by the transient hot wire method, and the modeling of the effective thermal conductivity of biphasic air-clay and water-clay media, but also triphasic unsaturated air-water-clay media. The prospect is the modeling of thermal and hydric transfer from the surface to the depth. - and the elaboration of a protocol of impregnation - hardening for wet clay dominated soils by HEMA resins. This impregnation allows the making of thin sections in these clay materials with conservation of their initial wet structures. The prospective is the quantitative petrography at the root - clay matrix interface along vertical profiles in clayey soils at different degrees of saturation and different structures.

Sols argileux

Dessiccation-Retrait

Marais côtiers

Drainage

Remontées capillaires

Évapotranspiration

Réserve utile

Stress hydrique

Stress salin

Conductivité thermique

Imprégnation-Polymérisation

Clay dominated soils

Desiccation-Shrinkage

Coastal marshlands

Drainage

Capillarity rise

Evapotranspiration

Available water capacity

Plant available water

Hydric stress

Salt stress

PAW profile modeling

Thermal conductivity

Impregnation-Hardening

577.57