Soil-root System Research Articles

Resistance to Water Flow in the Seminal Roots of Wheat

Water uptake by the seminal root system of wheat is described by a model which incorporates radial and axial resistance to flow in the root and the resistance to flow in the soil. In an experiment where wheat plants were dependent on subsoil water extracted from below 45 cm by one, three, or five seminal roots, calculations indicated that the axial resistance was the dominant resistance within the soil-root system and that flow rate changed predictably with changing axial resistance. The model also indicated that the observed shape of the metaxylem vessel in the seminal axes has important effects on the pattern of water uptake.

Resistance to water movement through wheat root systems

A three-layer electrical analogue model was used to calculate resistance to water movement through the roots of wheat plants growing in small weighing lysimeters. In one experiment the wheat was grown in two soil types; in a second experiment one soil type was used but different root systems were induced by controlling the water table before the start of the experimental period. Resistance calculations were based on hourly measurements of transpiration rate, leaf water potential and water uptake from three soil layers (qi), calculated from measurements of soil water potential at three depths. The number of main roots per stem (required for the model) and root surface area in each layer (Ai) were obtained from measurements of root lengths and diameters in soil cores taken at the end of each experiment. Estimates of the resistance to flow through stems led to estimates of ψ0), the water potential at the stem base, at any stem flow rate. Axial (main) root resistances (Rxi) were calculated from the Poiseuille equation. Values of the resistance to water movement through the roots in layer i were calculated from the set of equations describing uptake from each layer in terms of flow rates, potential gradients and resistances; these values, inserted in the solution for 1/10 from the set of three equations, yielded total root resistances (RT) and estimates of the effective soil moisture potential (^ψs) for the whole profile. (RT) ranged from 63.9 to 627.3 bar sec mm-3 (cf. stem resistance between 24 and 70 bar sec mm-3) and was inversely related to flow rate through the main roots, which indicated a constant potential drop (^ψs – ψ0) of about 10 bars, irrespective of soil type or root system. Radial root resistances, estimated as At(<ψsi – ψ0)/qi, ranged from 4.6 x 104 to 4.2 x 106 bar sec mm-l and were inversely related to qi. Inaccuracies in estimates of Rxi do not affect the results much and the model used is potentially valuable as a framework for field research.

The Use of Tree-cutting Techniques in the Study of the Water Relations of MaturePinus sylvestrisL.

This paper gives a description of ‘tree cutting’ under water in an attempt to understand some of the basic problems concerning the water relations of trees. A large resistance in the soil-root system is confirmed. The effect of changes in leaf water potential on cutting (which is essentially a change in turgor potential) is shown to affect stomatal resistance (rs) and thus transpiration depending on environmental conditions. Water uptake rates and evaporation estimates compare well at low rates. The correspondence is less good at higher rates and this is thought to be due to rs of cut trees being less limited under conditions of high evaporative demand. Transpiration was found to be negligible during rainfall. The radial changes occurring diurnally in control trees are markedly modified in cut trees presumably because of the removal of the root-soil resistance.

Measurement of water fluxes and potentials in a single root-soil system

The construction and operation of a novel tensiometer-potometer system capable of measuring the xylem water potential and flux of water into the root is described. The validity of its measurements has been illustrated and it was shown that a unique linear relationship exists between the resistance to water flow and the water status of the root tissues.

Simulation of Post-Irrigation Moisture Movement

The transpiration-induced moisture removal by the plant roots is represented by a negative source term in the Darcy equation. When the soil is wetted to near saturation, the moisture flow is initially downward due to gravity. As transpiration dries the upper soil layers, capillary suction reverses the Darcian flow. The upward water flux through the soil has a maximum, which occurs high in the root zone initially and gradually moves downward. Throughout much of the time periods studied there was downward flow in portions of the soil-root system. Very little water, if any, was obtained by the plants from below the root zone, but considerable moisture was often lost to this region. As the soil-root system dries, a point is reached at which the Darcian moisture flux in the soil can be neglected, and the moisture removal process can be described by local extraction alone. When this occurs, the root geometry assumes major importance in determining the water supply available to a plant.

Application of an Extraction‐Term Model to the Study of Moisture Flow to Plant Roots1

AbstractA one‐dimensional extraction‐term model is used to simulate the moisture flow and removal process in the vicinity of plant roots. The dependence of model results on root depth and soil type are investigated. Moisture contents, root moisture absorption rates and soil moisture fluxes are computed and discussed for several hypothetical root systems in a sandy soil and in a clay soil.The model is solved numerically with a procedure based on the Douglas‐Jones predictor‐corrector method. Results indicate that moisture extraction by the roots from soil in their immediate vicinity is the dominant process, with Darcian flow in the root zone playing a smaller but often significant role.Extraction‐term models are versatile and seem able to describe many of the phenomena associated with moisture removal by the roots of transpiring plants.

INFLUENCE OF TEMPERATURE ON THE AVAILABILITY OF IRON TO AN OAT CROP

The availability of Fe-59 added as FeCl3∙6H2O to sandy-textured soils decreased in relation to the total amount of Fe taken up by oats when the temperature of the soil-root system was raised from 10 to 27 °C. When the soil temperature was raised to 27 °C, the ratio of Fe-59/total-Fe in the forage material of the oats decreased over the entire temperature range, even though maximum yield and total-Fe uptake occurred near 20 °C. Changing the aerial environment by lowering the dark-period air temperature from 25 to 10 °C markedly reduced the yield of dry matter and raised the concentration of total-Fe in the plant but did not consistently affect the ratio Fe-59/total-Fe. Incubating the soil for 30 days prior to adding the Fe-59 and seeding also reduced the proportion of Fe-59 in the plant material.

THE INFLUENCE OF SIMAZINE ON SHOOT AND ROOT GROWTH OF APPLES AND PLUMS

Summary. In loamy soil with a low humus content (0·8% organic carbon) simazine at a concentration of 2′5 ppm reduced growth of shoots, roots and trunk diameter in 1‐year‐old scions of five apple varieties on M IX rootstock. The most susceptible was Cox's Orange Pippin; 5 ppm was lethal for this variety only. In experiments with vertically divided pots, where one part of the root system developed in soil with simazine (2–5 ppm and 5–0 ppm for apple and 5·0 ppm for plum) and the other part in simazine‐free soil, there was less effect on shoot growth and less leaf damage than where all the soil contained simazine. Growth of that part of the root system in soil containing simazine was stimulated.

Numerical analysis of the convection and diffusion of solutes to roots

A numerical method is given for solving a partial differential equation describing the radial movement of solutes through a porous medium to a root. Computer programmes based on the method were prepared and used to obtain solutions of the equation for an idealized root-soil system in which a solute is transported to the root by convection but is not taken up by the root. Various patterns of water uptake were considered, the most complex being a diurnally varying uptake from soil in which the water content is decreasing. The solutions suggest that the maximum build-up of solute at the surface of a root is trivial if the root is growing in a medium such as agar, in which the diffusion coefficient of the solute is high, but may be considerable, with a concentration up to 10 times higher than the average concentration in the soil solution, when the root is growing in a fairly dry soil. The application of the method to systems other than the one considered in detail is discussed.

Effects of Atmospheric Desiccation on the Subsequent Absorption of Nitrate and Phosphate and the Exudate of Detopped Tomato Root Systems

Removal of detopped tomato root systems from water for 1 hr caused a reduction in the subsequent absorption of phosphate when they were placed in nutrient solution. The treatment did not change the phosphate content or volume of the exudate. These data are compared with results usually obtained using plants or root systems in dry soil or in solutions of high osmolarity.

Transpiration response of Atriplex nummularia Lindl. and upland cotton vegetation to soil-moisture stress

The effect of increasing soil-moisture stress upon the transpiration of a stand of Atriplex nummularia Lindl., a native Australian saltbush, and of the American Upland cotton, variety Empire, was investigated under open glasshouse conditions in the Australian semi-arid zone. By growing the plants at a high density and restricting their height to 18 cm, each species formed a low uniform stand of vegetation. The plants were grown in sandy clay loam soil contained in two large weighing lysimeters and in surrounding boxes that formed a guard area. In each experiment soil-moisture stress was imposed upon the vegetation growing in one lysimeter and the surrounding guard area, by withholding water until the plants became acutely wilted, while the soil in the second lysimeter and in its guard area was maintained close to field capacity. The effect of the water stress treatment upon transpiration was determined by recording the daily water loss from the two lysimeters. The experiment was carried out in late summer and repeated in winter with each species. No signs of water deficit were ever seen among the plants of either species in the watered area of the vegetation, even on the hottest days experienced when peak transpiration rates of 8 mm/day and 12 mm/day were recorded for the A: nummularia and cotton vegetation respectively. The transpiration responses of both the Atriplex and cotton vegetation to increasing soil-moisture stress were very similar, while in the summer and winter experiments the effective soil-moisture tension range over which transpiration was reduced was approximately the same also, i.e., from 10–60 bars. In each experiment the falling transpiration rate showed an approximately linear relationship to the logarithm of soil-moisture tension. Quantitative differences were found between the summer and winter transpiration rates, in the range limited by soil-moisture tension. Thus, for the same soil-moisture tension the transpiration rate of both species was initially about 3–4 times greater in the summer experiments than in the winter ones. As the soil-moisture tension increased, the reduction in the transpiration rate of each species in the summer experiment was much greater than in the respective winter one, and the reduction in the rate occurred about 5 times more rapidly. However, because of the lower level of transpiration in the winter, the summer transpiration rates at any given soil-moisture tension did not fall below the corresponding winter values. That the sensitivity of transpiration to increasing soil-moisture tension was relatively unaffected by the climatic change from summer to winter in both cotton and Atriplex may have been a reflection of the particular soil root system present in the experiments. Alternatively, this may have been caused by changes in the anatomy or physiology of each species in wintertime. The ability of A. nummularia to survive rainless periods under semi-arid climatic conditions is considered. It is suggested that since no special characteristic that would aid drought survival was found, this ability probably depends upon a feature that did not develop in the experiments. Such a feature could be the development of an extensive root system.

Phosphorus Absorption by Corn Roots as Affected by Moisture and Phosphorus Concentration

AbstractThe relative uptake of P by corn seedlings was 100, 94, 80, 50, and 35 for 1/3, 1/2, 1, 3 and 9 bars soil moisture tension, respectively. Uptake of P was a linear function of the soil moisture content for a given soil. Thickness of moisture films, diffusion path length, degree of hydration and elongation of the roots appeared to be the factors controlling P uptake in relation to moisture tension. Uptake of P at constant moisture tension on soils differing in texture and soluble P level was a linear function of solution P concentration, but the range of concentration investigated was small. Phosphorus uptake from a soilroot system differs appreciably from a solution‐root system, which suggests that the soil introduces a limiting factor in rate of P uptake.