Solute Movement in the Soil-root System PDF Download
Are you looking for read ebook online? Search for your book and save it on your Kindle device, PC, phones or tablets. Download Solute Movement in the Soil-root System PDF full book. Access full book title Solute Movement in the Soil-root System by Peter Hague Nye. Download full books in PDF and EPUB format.
Author: Peter Hague Nye
Publisher: Univ of California Press
ISBN: 9780520034518
Category : Nature
Languages : en
Pages : 360
Get Book Here
Book Description
Author: Peter Hague Nye
Publisher: Univ of California Press
ISBN: 9780520034518
Category : Nature
Languages : en
Pages : 360
Get Book Here
Book Description
Author: P. B. Tinker
Publisher: Oxford University Press
ISBN: 0195352319
Category : Science
Languages : en
Pages : 465
Get Book Here
Book Description
This is a completely revised edition of the previously titled Solute Movement in the Soil-Root System. It describes in detail how plant nutrients and other solutes move in the soil in response to plant uptake, and it provides a basis for understanding processes in the root zone so that they can be modeled realistically in order to predict the effects of variations in natural conditions or our own practices.
Author: M.B. Kirkham
Publisher: Academic Press
ISBN: 0124200788
Category : Science
Languages : en
Pages : 599
Get Book Here
Book Description
Principles of Soil and Plant Water Relations, 2e describes the principles of water relations within soils, followed by the uptake of water and its subsequent movement throughout and from the plant body. This is presented as a progressive series of physical and biological interrelations, even though each topic is treated in detail on its own. The book also describes equipment used to measure water in the soil-plant-atmosphere system. At the end of each chapter is a biography of a scientist whose principles are discussed in the chapter. In addition to new information on the concept of celestial time, this new edition also includes new chapters on methods to determine sap flow in plants dual-probe heat-pulse technique to monitor water in the root zone. - Provides the necessary understanding to address advancing problems in water availability for meeting ecological requirements at local, regional and global scales - Covers plant anatomy: an essential component to understanding soil and plant water relations
Author: George M. Briggs
Publisher:
ISBN: 9781942341826
Category :
Languages : en
Pages :
Get Book Here
Book Description
Author: T.J. Flowers
Publisher: Springer Science & Business Media
ISBN: 9401122709
Category : Science
Languages : en
Pages : 187
Get Book Here
Book Description
The study of solute transport in plants dates back to the beginnings of experimental plant physiology, but has its origins in the much earlier interests of humankind in agriculture. Given this lineage, it is not surprising that there have been many books on the transport of solutes in plants; texts on the closely related subject of mineral nutrition also commonly address the topic of ion transport. Why another book? Well, physiologists continue to make new discoveries. Particularly pertinent is the characterisation of enzymes that are able to transport protons across membranes during the hydrolysis of energy-rich bonds. These enzymes, which include the H + -A TPases, are now known to be crucial for solute transport in plants and we have given them due emphasis. From an academic point of view, the transport systems in plants are now appreciated as worthy of study in their own right-not just as an extension of those systems already much more widely investigated in animals. From a wider perspective, understanding solute transport in plants is fundamental to understanding plants and the extent to which they can be manipulated for agricultural purposes. As physiologists interested in the mechanisms of transport, we first set out in this book to examine the solutes in plants and where are they located. Our next consideration was to provide the tools by which solute movement can be understood: a vital part of this was to describe membranes and those enzymes catalysing transport.
Author: Zoe G. Cardon
Publisher: Elsevier
ISBN: 0080493041
Category : Technology & Engineering
Languages : en
Pages : 235
Get Book Here
Book Description
Below the soil surface, the rhizosphere is the dynamic interface among plant roots, soil microbes and fauna, and the soil itself, where biological as well as physico-chemical properties differ radically from those of bulk soil. The Rhizosphere is the first ecologically-focused book that explicitly establishes the links from extraordinarily small-scale processes in the rhizosphere to larger-scale belowground patterns and processes. This book includes chapters that emphasize the effects of rhizosphere biology on long-term soil development, agro-ecosystem management and responses of ecosystems to global change. Overall, the volume seeks to spur development of cross-scale links for understanding belowground function in varied natural and managed ecosystems. - First cross-scale ecologically-focused integration of information at the frontier of root, microbial, and soil faunal biology - Establishes the links from extraordinarily small-scale processes in the rhizosphere to larger-scale belowground patterns and processes - Includes valuable information on ecosystem response to increased atmospheric carbon dioxide and enhanced global nitrogen deposition - Chapters written by a variety of experts, including soil scientists, microbial and soil faunal ecologists, and plant biologists
Author: P. B. Tinker
Publisher: Oxford University Press
ISBN: 9780195352313
Category : Science
Languages : en
Pages : 472
Get Book Here
Book Description
This is a completely revised edition of the previously titled Solute Movement in the Soil-Root System. It describes in detail how plant nutrients and other solutes move in the soil in response to plant uptake, and it provides a basis for understanding processes in the root zone so that they can be modeled realistically in order to predict the effects of variations in natural conditions or our own practices.
Author:
Publisher: Springer Science & Business Media
ISBN: 1461228948
Category : Technology & Engineering
Languages : en
Pages : 231
Get Book Here
Book Description
In the past 10 years, there has been a resurgence in interest in soil management and conservation of the soil resource. With the knowledge we have accumulated in the past 100 years, there is the possibility of developing new and innovative ways of effectively managing the soil. The emphasis on sustainable agriculture requires that we understand how to utilize the soil as a viable living resource. To meet the world demand for food within the next 50 years requires a healthy and strong soil resource which can sustain production. With the dedication of the National Soil Tilth Laboratory in 1989, it was decided that one contribution the laboratory could make to agri cultural science would be to foster an exchange of information on soil management. The focus of that interchange centers on long-term soil management. If we are to fulfill the goals of sustainable agriculture, environmental quality, and feeding the world, there will have to be an increased understanding of how to effectively manage the soil. Long-term soil management requires integrated and interdisciplinary research to bring all of the information together in terms which would be applicable to all soils. To accomplish this goal a workshop is held each year, with the exchange of information focusing on a single topic within the framework of developing effective strategies for long-term soil management. With the forum to focus on an individual theme each year, the theme for the initial workshop was "Limitations to Plant Root Growth.
Author: Hans de Kroon
Publisher: Springer Science & Business Media
ISBN: 9783540001850
Category : Science
Languages : en
Pages : 424
Get Book Here
Book Description
In the course of evolution, a great variety of root systems have learned to overcome the many physical, biochemical and biological problems brought about by soil. This development has made them a fascinating object of scientific study. This volume gives an overview of how roots have adapted to the soil environment and which roles they play in the soil ecosystem. The text describes the form and function of roots, their temporal and spatial distribution, and their turnover rate in various ecosystems. Subsequently, a physiological background is provided for basic functions, such as carbon acquisition, water and solute movement, and for their responses to three major abiotic stresses, i.e. hard soil structure, drought and flooding. The volume concludes with the interactions of roots with other organisms of the complex soil ecosystem, including symbiosis, competition, and the function of roots as a food source.
Author: Jörg Richter
Publisher:
ISBN:
Category : Soil chemistry
Languages : en
Pages : 210
Get Book Here
Book Description
The approach followed in this book. Statics and kinetics. Dynamic approach. Balance approach. The system in thermodynamics. Fundamentals of the theory of potential. The macroscopic approach. Aggregation and buffering. The term "model". Classifying the processes in the soil. The organization of this book. Heat conduction in soils. Significance of heat dispersion in soils. Phenomena of heat dispersion. Examples of daily temperature courses in soils. Example of an annual course of the temperature. Heat conductivity and capacity in relation to soil composition and structure. Deriving the transport equation using local balance and principle of causality. Local balance for matter and energy without transformation. One-dimensional transport equation of matter and energy in a rigid system with continuous pores. The equation for heat transport. Analytical solutions of the heat transport equation with constant aT. The stationary case. Sudden change in temperature as boundary condition. Oscillating temperature as boundary condition. Numeriacal solution of the heat transport equation with constant aT. Heat balance of the soil and heat conversion. Estimating the soil-absorbed energy. Heat to evaporate 1 mm water. Gas regime of soils. The significance of the gas regime in the soil. Phenomena in soil gas regime. Profiles of CO2 and O2 concentrations in the soil. Cycles and depth profiles of CO2 production. Parameters of the gas regime in soils. The apparent diffusion coefficient Ds. The storage of gases in the soil. Quantitative description of the gas regime in soils. Extending the transport equation. Partial pressure and diffusive gas transport. Solving the equation of gas regime. An analytical solution for the stationary case. Numerical solution for a stationary example. Applications of the gas transport and gas regime equation. The measurement of the diffusion coeficient Ds. The "tortuous" macropore as a structure model. Vapour flow in the soil. Micro-anoxia as a problem of aeration, and the redoxpotencial Eh. Soil water regime. The significance of soil water; annual balances. Phenomena of soil water flow. Water tension and water content profiles in the soil. Flows at the boundary area and in the soil. Hydraulic conductivity and the moisture retention curve. The hydraulic conductivity K( m). The moisture retention curve m(0). The water regime equation. The local water balance. The equation for the water flow qw. The hydraulic potential h. Different formulations of the water transport equation. Characteristic flow conditions of water in the bare soil. Equilibrium and quasi-equilibrium. Stationary and quasi-stationary conditions. Non-stationary flow. Applications and numerical solutions for the water regime equation. Moisture equilibrium in the soil. stationary flow in the soil during drying in summer. Solution methods for non-stationary flow. Simple water regime models for the flat, homogeneous cropped soil; the root uptake function P(z,t). Calculating the evapotranspiration E. The water regime of a wheat field on a loess-Parabraunerde. Regime of matter in soils. Significance of "matter" in the soil. Extension of the transport the transport models. Phenomena of ion flows. Movement of non-interacting ions during winter. Movement of interacting ions during winter. Paramenters of solute transport. Transport parameter: effective dispersion coefficient Db. Quantity/intensity relation for compenents that do interact with the soil matrix; the specific storage capacity B. Specific storage capacity C (and the diffusion coefficient D). Coupled transport flows of components that do not interact with the soil matrix. General description of coupled transport. Transport of dissolved non-interacting components in the soil. Particle charge. Introduction to reaction dynamics. Fundamentals of the course of reactions. Order of elementary reactions in homogeneous systems. A special case: second-order reactions of sigmoidal shape. Complex reactions in homogeneous systems. Heterogeneous reactions (interactions with the surfaces of solids). Models for reactive components and ions in the soil. Dynamic description of interactions of substances with the solid phase. Description of interactions of ions with charged surfaces of the solid phase (ions-exchange). Simple regime models of substances in the soil. Models for nitrification and simultaneous movement of nitrogen. Simulating the nitrogen regime of loess field soils during winter. A site model for the displacement of physically interacting ions for the example potassium. Simulating the degradation of herbicides in soils. Simulating the behaviour of heavy metals in the soil. "Complete"models of material components regime. Looking ahead. Beyond the assumptions. The soil as a non-rigid solid. Mechanical deformations and changes of the state of stress. Mechanical cause-and-effect relations. Changes of the parameters with mechanical deformations. The explicit modelling of nutrient uptake by plants. Field and regional models. Simulating solute transport in heterogeneous pore systems. Geostatistical formulation of spatial variability. Combining deterministic and stochastic approaches: Monte-Carlo simulation of salt transport. Alternative approaches: plate and compartment models. Modelling soil development. Appendix. Numerical solutions for non-stationary water transport and for solute transport under stationary flow conditions. Vertical solute movement under stationary flow conditions. Vertical water transport. Difference formulationwith the help of the Taylor equation. Gas solubilities in water. Conversion of units. List of symbols and indices.
