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Soil-Nutrient Relationships
Cation exchange
The ‘soil cations’ essential for plant growth include ammonium, calcium, magnesium, and
potassium. There are three additional ‘soil cations,’ which are not essential plant elements but
affect soil pH. The additional ‘soil cations’ include sodium, aluminum and hydrogen.
Soil cations that are essential to plant growth
Ammonium
Calcium
Magnesium
Potassium
Soil cations that affect soil pH
Sodium
Aluminum
Hydrogen
The major distinguishing characteristic of cations is their positive charge. Just like a magnet, a
positive charge is strongly attracted to a negative charge. When soil particles have a negative
charge, the particles attract and retain cations. These soils are said the have a cation exchange
capacity. Although most soils are negatively charged and attract cations, some Hawaii soils are
exceptions as we will see.
The ‘soil cations’ are further divided into two categories. Ammonium, calcium, magnesium,
potassium, and sodium are known as the ‘base cations,’ while aluminum and hydrogen are
known ‘acid cations.’
Base Cations
Ammonium
Calcium
Magnesium
Potassium
Sodium*
* Unlike the other base cations, sodium is not an essential element for all plants. Soils that
contain high levels of sodium can develop salinity and sodicity problems.
Acid Cations
Aluminum
Hydrogen
The words ‘base’ and ‘acid’ refer to the particular cation’s influence on soil pH. As you might
suspect, a soil with a lot of acid cations held by soil particles will have a low pH. In contrast, a
highly alkaline soil predominately consists of base cations.
Cations in the soil compete with one another for a spot on the cation exchange capacity.
However, some cations are attracted and held more strongly than other cations. In decreasing
holding strength, the order with which cations are held by the soil particles follows: aluminum,
hydrogen, calcium, potassium and nitrate, and sodium.
Figure 2. CEC values of various soil type, media, and minerals. Soils which have high amounts
of organic matter and moderately weathered clays tend to have high CECs. As soils become
highly weathered, the CEC of the soil decreases. Sandy soils, too, generally have lower CEC
values. This is due to the lesser surface of sandy particles in comparison with clay minerals,
which decreases the ability of sand particles to hold and retain nutrients.
Source: Brady and Weil. 2002. Elements of the Nature and Properties of Soil. Prentice Hall,
New Jersey.
Anion exchange
In the tropics, many highly weathered soils can have an anion exchange capacity. This means
that the soil will attract and retain anions, rather than cations. In contrast to cations, anions are
negatively charged. The anions held and retained by soil particles include phosphate, sulfate,
nitrate and chlorine (in order of decreasing strength). In comparison to soils with cation
exchange capacity, soils with an anion capacity have net positive charge. Soils that have an
anion exchange capacity typically contain weathered kaolin minerals, iron and aluminum oxides,
and amorphous materials. Anion exchange capacity is dependent upon the pH of the soil and
increases as the pH of the soil decreases.
Base Saturation
Base saturation is a measurement that indicates the relative amounts of base cations in the soil.
By definition, it is the percentage of calcium, magnesium, potassium and sodium cations that
make up the total cation exchange capacity. For example, a base saturation of 25 % means that
25 % of the cation exchange capacity is occupied by the base cations. If the soil does not
exhibit an anion exchange capacity, the remainder 75 % of the CEC will be occupied by acid
cations, such as hydrogen and aluminum. Generally, the base saturation is relatively high in
moderately weathered soils that formed from basic igneous rocks, such as the basalts of
Hawaii. The pH of soil increases as base saturation increases.
In contrast, highly weathered and/or acidic soils tend to have low base saturation.
Movement of nutrient from soil to root
There are three basic methods in which nutrients make contact with the root surface for plant
uptake. They are root interception, mass flow, and diffusion.
Root interception: Root interception occurs when a nutrient comes into physical contact
with the root surface. As a general rule, the occurrence of root interception increases as
the root surface area and mass increases, thus enabling the plant to explore a greater
amount of soil. Root interception may be enhanced by mycorrhizal fungi, which colonize
roots and increases root exploration into the soil. Root interception is responsible for an
appreciable amount of calcium uptake, and some amounts of magnesium,
zinc andmanganese.
Mass flow: Mass flow occurs when nutrients are transported to the surface of roots by
the movement of water in the soil (i.e. percolation, transpiration, or evaporation). The
rate of water flow governs the amount of nutrients that are transported to the root
surface. Therefore, mass flow decreases are soil water decreases. Most of the nitrogen,
calcium, magnesium, sulfur, copper, boron, manganese andmolybdenum move to
the root by mass flow.
Diffusion: Diffusion is the movement of a particular nutrient along a concentration
gradient. When there is a difference in concentration of a particular nutrient within the
soil solution, the nutrient will move from an area of higher concentration to an area of
lower concentration. You may have observed the phenomenon of diffusion when adding
sugar to water. As the sugar dissolves, it moves through parts of the water with lower
sugar concentration until it is evenly distributed, or uniformly concentrated. Diffusion
delivers appreciable amounts of phosphorus, potassium, zinc, and iron to the root
surface. Diffusion is a relatively slow process compared to the mass flow of nutrients
with water movement toward the root.
Nutrient Uptake into the root and plant cells
Before both water and nutrients are incorporated into plants, both must first be absorbed by
plant roots.
UPTAKE OF WATER AND NUTRIENTS BY ROOTS
Root hairs, along with the rest of the root surface, are the major sites of water and
nutrient uptake.
Water moves into the root through osmosis and capillary action.
Soil water contains dissolved particles, such as plant nutrients. These dissolved particles
within soil water are referred to as solute. Osmosis is the movement of soil water from
areas of low solute concentration to areas of high solute concentration. Osmosis is
essentially the diffusion of soil water.
Capillary action results from water’s adhesive (attraction to solid surfaces) and cohesion
(attraction to other water molecules). Capillary action enables water to move upwards,
against the force of gravity, into the plant water from the surrounding soil.
Nutrient ions move into the plant root by diffusion and cation exchange.
Diffusion is the movement of ions along a high to low concentration gradient.
Cation ion exchange occurs when nutrient cations are attracted to charged surface of
cells within the root, called cortex cells. When cation exchange occurs, the plant root
releases a hydrogen ion. Thus, cation exchange in the root causes the pH of the
immediately surrounding soil to decrease.
Once water and nutrient ions enter the plant root, they move though spaces that exist
within the root tissue between neighboring cells.
Water and nutrients are then transported into the xylem, which conducts water and
nutrients to all parts of the plant.
Once water and nutrients enter the xylem, both can be transported to other parts in the plant
where the water and nutrients are needed. The basic outline of how nutrient ions are absorbed
by plant cells follows.
ABSORPTION OF NUTRIENTS INTO PLANT CELLS
Plant cells contain barriers (plasma membrane and tonoplast) that selectively regulate
the movement of water and nutrients into and out of the cell. These cell barriers are:
permeable to oxygen, carbon dioxide, as well as certain compounds.
semi-permeable to water.
selectively permeable to inorganic ions and organic compounds, such as amino acids
and sugars.
Nutrient ions may move across these barriers actively or passively
Passive transport is the diffusion of an ion along a concentration gradient. When the
interior of the cell has a lower concentration of a specific nutrient than the outside of the
cell, the nutrient can diffuse into the cell. This type of transport requires no energy.
Active transport is the movement of a nutrient ion into the cell that occurs against a
concentration gradient. Unlike passive transport, this type of movement requires energy.
Nutrient Mobility
WITHIN PLANT
An important characteristic of some nutrients is the ability to move within the plant tissue. In
general, when certain nutrients are deficient in the plant tissue, that nutrient is able translocate
from older leaves to younger leaves where that nutrient is needed for growth. Nutrients with this
ability are said to be mobile nutrients, and include nitrogen, phosphorus,
potassium, magnesium, and molybdenum. In contrast, immobile nutrients do not have the
ability to translocate from old to new growth. Immobile nutrients include calcium, sulfur, boron,
copper, iron, manganese, and zinc.
Nutrient mobility, or immobility, provides us with special clues when diagnosing deficiency
symptoms. If the deficiency symptom appears first in the old growth, we know that the deficient
nutrient is mobile. On the other hand, if the symptom appears in new growth, the deficient
nutrient is immobile.
WITHIN THE SOIL
Mobility of a nutrient within the soil is closely related to the chemical properties of the soil, such
as CEC and AEC, as well as the soil conditions, such as moisture. When there is sufficient
moisture in the soil for leaching to occur, the percolating water can carry dissolved nutrients
which will be subsequently lost from the soil profile. The nutrients which are easily leached are
usually those nutrients that are less strongly held by soil particles. For instance, in a soil with a
high CEC and low AEC, nitrate (an anion) will leach much more readily than calcium (a cation).
Additionally, in such a soil, potassium (a monovalent cation) will leach more readily than calcium
(divalent cation) since calcium is more strongly held to the soil particles than potassium.
Silica from minerals also dissolves and leaches from the soil profile during the processes of
weathering. It is this dissolution and leaching that transforms primary minerals to the more
weathered, secondary minerals that make up the finely-textured soils of Maui.
Soil acidity and liming
Soil pH is a useful indicator of the relative acidity or alkalinity of a soil. The pH scale ranges from
0 to 14, and the soil is assigned a value from the pH scale to describe the acidity or alkalinity.
Since pH 7 falls midway along the scale, pH values that are equal to 7 are said to be neutral.
However, pH values that fall below 7 are acidic, while pH values above 7 are alkaline.
By definition, the pH of a soil is the measurement of the concentration of hydrogen ions in soil
water. Recall that the hydrogen ion is an acid cation. The greater the concentration of
hydrogen ions in the soil water solution, the lower the pH. In return, the lower the pH value, the
greater the acidity of the soil will be. The concentration of hydrogen ions in the soil solution is
directly proportionate to and in equilibrium with the hydrogen ions retained on the soil’s cation
exchange complex. Thus, the hydrogen ions retained by clay particles replenish, or buffer, the
hydrogen ions in soil water.