amount and size of the pore space. Soil is often considered as a three phase system, consisting of air, water and soil, (sand, silt and clay) figure I. Some organic matter is also usually present and will make up between 3% and 5% in typical soils. The air and water occupy the pore spaces between the soil particles. If the soil is oven dried then the pore spaces are only filled with air, conversely if the pore spaces are filled entirely with water, no air is present. When all the pore spaces are filled with water, the soil is said to be saturated. This would occur after a period of prolonged/heavy rain or irrigation. After a period of time, 1-3 days, some of the water will have drained from the soil under the effects of gravity; this water is removed from the larger pore spaces (macropores), in the soil. When the soil has reached this state it is considered to be at Field Capacity, (FC). At this time air has replaced the water in the macro pores, gravity is unable to remove further water.
The amount of pore space and the size of the pores will dictate the amount of water that can be held by the soil. Soils are made up of varying amounts of sand, silt and clay, the degree of aggregation of the particles is also variable. This is why different soils have differing amounts of soil moisture at a given state. Table I shows varying moisture percentages for different soils at given states.
Soil type
Coarse sand Sandy clay Clay
Clay loam
% moisture at % moisture at field capacity
permanent wilting point
8
29 42 34
4
19 25 28
Table I: Typical soil moisture states. Note the percentage of water that
remains in the soil at permanent wilting point. Water is present but the roots cannot exert enough tension to remove it.
Turfgrass roots can therefore only
Figure 1: Soil as a three phase system based on a typical silt loam soil when in a condition for good turfgrass growth.
Water in the soil is held between the soils particles by tension, the smaller the pore space the greater the tension exerted on the water. Gravity can only remove a given amount of water from the soil before the amount of tension on the water in the smaller pore spaces can not be overcome. Plant roots are able to exert and
extract water from the soil to much higher tensions than gravity; however at some point even the turfgrass roots cannot remove further moisture from the soil. When the soil has reached this condition it is said to be at Permanent Wilting Point, (PWP). It should be noted that moisture is still present in the soil but it is simply unavailable. Figure III.
remove water between the two conditions of field capacity and permanent wilting point. The moisture available to the plant between these two states is referred to as Readily Available Water, (RAW). Temperature moderation of soils occurs due to the insulating properties of the soil. During the summer, soil temperature at the surface is often much higher than the temperature at say 100mm below the surface, this allows the roots to function in what would be an otherwise, hostile environment. Cool season turf grasses have an optimum temperature range for shoot growth between 15O
C to 25O C and 18O C, while for root
growth the temperature range is between 10O
C (Beard, 1973).
Figure III: Illustration of differing soil water states
Toxins within the soil may be the result of human activity, plant roots, natural chemical reactions or micro-organisms. Organic chemicals are usually broken down into simple non-toxic compounds, however; metals and other toxic elements leave a residue which may be permanent unless leaching occurs (Rowell, 1994). Fortunately the trend today, is for organic fertilisers and pesticides. Which hopefully are leaving no long term traces within the soil as the compounds are degraded. Nutritional balance in turfgrass is importance for both survival and growth. The availability of the 16 essential elements (see figure IV), will determine how the turfgrass responds to environmental stress, recovery from damage, susceptibility to diseases and wear tolerance to name a few. While turfgrass managers may not be able to do much about the three elements which make up some 90-96% of a plants dry weight (Carbon, oxygen and hydrogen) as these are obtained predominantly from water and atmospheric sources, the remainder should be considered as a consumable resource obtained from the soil and which will require replacing at some stage. The soils water content, pH,
Figure IV; Mineral composition of a typical plant, adapted from Danneberger (1993).
Soils also have a facility to compensate for nutrient losses, by way of a process known as “buffering”. In well buffered soils, while the plant
removes its needs and some nutrients are lost, perhaps through leaching, the concentration of nutrients in the soil are maintained. A sandy soil for example can easily have nutrients added, but they are also easily lost, the opposite of this would be a clay soil, where the plants removal of nutrients only has a small effect on the overall amount that is held by the soil.
Each of these areas has a specific effect on turf grass and as we have looked at could be considered individually. It should however be apparent that if we affect one aspect we may to a greater or lesser extent affect one or all the others. A single maintenance practice carried out, perhaps to address a single issue or problem may in fact produce further benefits or indeed problems. It is this inter-relationship which needs to be understood by the turf grass manager.
REFERENCES:
Beard, J.B. (1973). Turfgrass: Science and Culture. Prentice Hall: New Jersey
Brady, N.C. and Weil, R.R. (2002). The nature and properties of soils. 13th ed. Prentice Hall: New Jersey
Danneberger, K.T. (1993). ‘Turfgrass Ecology and Management’, Francak & Foster: Clevelend
Rowell, D.L. (1994). Soil Science: Methods and applications. Prentice Hall:Harlow
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structure and texture as well as the turfgrass species, density, and vigour coupled with climatic conditions will combine to affect the requirements of the plant and the availability of the nutrients.
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