Nutrients uptake is at its greatest during tuber bulking up (intensive
volume increase process).
The amount of nutrients removed by a potato crop is closely related to
yield. Usually, twice the yield will result twice the removal of nutrients.
Nutrients need to be applied as accurately as possible to the zone of uptake,
slightly before, or at the time that the crop needs them. Failure to ensure
that each plant gets the right balance of nutrients can spoil crop quality and
reduce yield.
The highest requirement for potassium, as shown on Figure 4, is during
the bulking up stage of the tubers. The flowering of potato plants is an
indication when this morphological stage starts. Consequently, the ideal
side-dressing period with Multi-K™ would be during the tuber bulking stage.
Figure 4: Uptake of
macronutrient uptake by a whole potato plant
Source: Harris (1978)
The daily requirements of potato tubers during the critical bulking stage are 4.5 kg/ha N, 0.3 kg/ha P and 6.0 kg/ha K. Potassium requirements of potato tubers during the bulking stage are very high as they are considered to be luxury consumers of potassium. Daily yield increase during the critical tuber bulking stage can reach 1000 - 1500 kg/ha/day. Therefore, it is important to supply the required plant nutrients during the tuber bulking stage in right N-P-K ratio and in ample quantities.
Table 1: Summary of
main functions of plant nutrients
|
Nutrient |
Functions |
|
Nitrogen (N) |
Synthesis of
proteins (growth and yield). |
|
Phosphorus (P) |
Cellular division
and formation of energetic structures. |
|
Potassium (K) |
Transport of
sugars, stomata control, cofactor of many enzymes, reduces susceptibility to
plant diseases. |
|
Calcium (Ca) |
A major building
block in cell walls, and reduces susceptibility to diseases. |
|
Sulfur (S) |
Synthesis of
essential amino acids cystine and methionine. |
|
Magnesium (Mg) |
Central part of
chlorophyll molecule. |
|
Iron (Fe) |
Chlorophyll
synthesis. |
|
Manganese (Mn) |
Necessary in the
photosynthesis process. |
|
Boron (B) |
Formation of cell
wall. Germination and elongation of pollen tube. Participates in
the metabolism and transport of sugars. |
|
Zinc (Zn) |
Auxins synthesis. |
|
Copper (Cu) |
Influences in the
metabolism of nitrogen and carbohydrates. |
|
Molybdenum (Mo) |
Component of
nitrate-reductase and nitrogenase enzymes. |
Table 2: Effects of
the nutrients and the potassium source on the yield quality
|
Parameter |
Increase in
dosage of |
Application
of KCl in comparison to chloride-free K (-Cl) |
||
|
Nitrogen |
Phosphorus |
Potassium |
||
|
Tuber size |
↑ |
No effect |
↑ |
Chloride-free K
helps increasing size |
|
Sensitivity to
mechanical damage |
↑ |
↓ |
↓ |
No information |
|
Tuber
blackening 1 |
↑ |
No effect |
No effect |
KCl is more
effective than (-Cl) |
|
% dry
matter 2 |
↓ |
↑Slight effect |
↑ |
Some reports
claim that heavy applications of KCl can result in a lower dry matter, this
might be due to the chloride effect |
|
% starch 3 |
↓ |
↑ |
↑ |
Some reports
claim that heavy applications of KCl can result in a lower dry
matter, this might be due to the chloride effect |
|
% protein |
↑ |
↓ |
Conflicting
results |
Chloride-free K
helps increasing content |
|
% reducing sugars |
Inconsistent |
↑ |
↓ |
No difference |
|
Taste |
↓ |
↑ |
No effect |
Chloride-free K
is better |
|
Blackening after
cooking |
↑ |
No effect |
|
|
1 Blackening is caused by oxidation of phenol compounds when skin is
exposed.
2 A high percentage of dry matter is required in potatoes for
industry.
3 High concentrations are desirable. The characteristic is
correlated to the specific gravity.
Nitrogen (N)
Adequate N management is one of the most important factors required to obtain high yields(Fig. 7) of excellent quality potatoes. An adequate early season N supply is important to support vegetative growth.
Excessive soil N, applied late in the season delays maturity of the tubers and result in poor skin set, which harms the tuber quality and storage properties. Potatoes are a shallow-rooted crop, generally growing on sandy, well-drained soils. These soil conditions frequently make water and N management difficult since nitrate is susceptible to leaching losses. On these sandy soils, it is recommended that potatoes receive split applications of N during the growing season. This involves applying some of the total N requirement prior to planting and applying the remainder during the season with side-dress applications or through the irrigation system by Nutrigation™ (fertigation).
The period of highest N demand varies by potato variety and is related to cultivar characteristics, such as root density and time to maturity. Petiole analysis during the growing season is a useful tool, allowing growers to determine the N status of the crop and respond in a timely manner with appropriate nutrients.
A balanced ammonium / nitrate ratio is very important at planting time. Too much ammonium-nitrogen is a disadvantage as it reduces root-zone pH and thereby promotes Rhizoctonia disease. Nitrate-nitrogen enhances the uptake of cations such as calcium, potassium and magnesium, required for elevated specific gravity values
Nitrogen Assessment
Soil testing to a depth of 60 cm. in the spring is critical to
planning an effective and efficient N management program. Post-harvest
soil samples may help growers to select succeeding crops, which will make
maximum use of the residual N after the potato crop.
The nitrogen demand by the crop during tuber bulking may be 2.2 to 3.0
kg/ha/day. Petiole nitrate sampling allows for in-season monitoring of the
crop’s nutrient status. Collecting the 4th petiole from
30 – 50 randomly selected plants throughout the field (Fig. 10) is recommended.
Tissue samples are often collected weekly to track changes in nitrate levels,
and to plan supplemental fertilizer applications, should levels drop below
optimum.
Critical petiole nitrate-levels decline as the potato crop develops and matures. Generally, petiole nitrate-N levels at tuber bulking are 10,000 ppm = low, 10,000-15,000 ppm = medium, >15,000 ppm = sufficient. (Fig. 1
Phosphorus (P)
Phosphorus is important for early root and shoot development, providing
energy for plant processes such as ion uptake and transport. Roots absorb
phosphate ions only when they are dissolved in the soil water. Phosphorus
deficiencies can occur even in soils with abundant available P, if drought, low
temperatures, or disease interfere with P diffusion to the root, through the
soil solution. These deficiencies will result in stunt root development and
inadequate function.
At the tuber initiation stage, an adequate supply of phosphorus ensures
that optimum number of tubers is formed. Following the tuber initiation,
phosphorus is an essential component for starch synthesis, transport and
storage.
Recent research suggests that modifications to P fertilizer, such as
polymer additives, humic substances, and coatings may be beneficial in
improving P uptake and potato production.
Figure 10: The structure of the 4th leaf on a potato plant
Potassium (K)
Potato plants take up large quantities of potassium throughout the
growing season. Potassium has an important role in the control of the plant water
status and internal ionic concentration of the plant tissues, with a special
focus on the stomatal functioning.
Potassium plays a major positive role in the process of nitrate
reduction within the plant. Where large amounts (e.g. >400 kg/ha K2O) are to be
applied, in temperate conditions it is advisable to split the dressings 6-8
weeks apart.
Potatoes require large amounts of soil K, since this nutrient is crucial
to metabolic functions such as the movement of sugars from the leaves to the
tubers and the transformation of sugar into potato starch. Potassium
deficiencies reduce the yield, size, and quality of the potato crop. A lack of
adequate soil K is also associated with low specific gravity in potatoes.
Potassium deficiencies impair the crop’s resistance to diseases and its
ability to tolerate stresses such as drought and frost. Applying K fertilizer
with a broadcast application prior to planting is most commonly recommended. If
the K is band-applied, the rates should be kept below 45 kg K2O/ha to avoid any
salt injury to the developing sprouts.
Selection of the
best K fertilizer
The source of potassium plays an important role on the quality and the yield of potato tubers. By comparing different sources of K, Multi-K™ potassium nitrate was found to increase the dry matter ontent and the yield significantly higher than other sources of K (Fig. 12 & 13). This study was done on different cultivars and all of them responded with higher tuber yield to Multi-K™ treatment(F
The potato's specific gravity and the chips color are important parameters for the processing potatoes industry. Both of these parameters are responding favourably to Multi-K™ potassium nitrate treatments as compared to other sources of K fertilizers ,
Beside the favourable effect of Multi-K™ on the quality and yield of potato tubers, it also improves the shelf life of the tubers in storage
Calcium (Ca)
Calcium is a key component of cell walls, helping to build a strong structure
and ensuring cell stability. Calcium-enriched cell walls are more resistant to
bacterial or fungal attack. Calcium also helps the plant adapt to stress by
influencing the signal chain reaction when stress occurs. It also has a key
role in regulating the active transport of potassium for stomatal opening.
Magnesium (Mg)
Magnesium has a central role in photosynthesis, as its atom is present
in the centre of each chlorophyll molecule. It is also involved in various key
steps of sugar and protein production as well as the transport of sugars in the
form of sucrose from the leaves to the tubers.
Yield increases of up to 10% were obtained in trials in which regular
application of magnesium fertilizers has been practiced .
Sulphur (S)
Sulphur reduces the level of common and powdery scab. This effect is
related to a reduction in the soil pH where sulphur is applied in its elemental
form.
2.3 Nutritional disorders in potatoes
Nitrogen
Nitrogen deficiency is manifested by reduced growth pale leaves,
and results in reduced tuber yield (size and number). The deficiency
is made worse by extrenme soil pH (low or high), low organic matter,
drought conditions or heavy irrigation (Fig. 18).
Nitrogen excess causes delayed maturity, excessive top growth, hollow
heart & growth cracks, increased susceptibility to biotic diseases, reduced
tuber specific gravity and difficulty in vine ‘burning’ before harvest.
Figure 18:
Characteristic nitrogen (N) deficiency symptoms
Phosphorus
Typical symptoms and syndroms related with phosphorus deficiency are:
fewer tubers, smaller tubers, stunted plants, yellowing of older leaves, small
dark green younger leaves (Fig. 19).P deficiency leads to reduced early vigor,
delayed maturity and reduced yields.
Excessive phosphorus, when present, ties up other elements such as
calcium and zinc, inducing thereby their deficiencies.
Figure 19:
Characteristic phosphorus (P) deficiency symptoms
Potassium
Potassium deficiency retards nitrogen uptake, slows down plant growth
and leads to reduced yields, inferior quality, and poor disease resistance.
Typical symptoms of K deficiency are necrosis of leaf margins, premature leaf
senescence (Fig. 20)
Excessive potassium causes reduced tuber specific gravity and reduced
calcium and/or magnesium uptake. It also degrades soil structure.
Figure 20:
Characteristic potassium (K) deficiency symptoms
Calcium
Calcium deficiency interferes with root growth, causes deformation of
foliage growth tips, and may result in reduced yields and poor quality.
Calcium-deficient potato tubers have reduced storage capability. Low calcium
levels in the soil result in poorer soil structure.
Typical symptoms of calcium deficiency are yellow curled leaves on upper
leaves, tip burns, and small chlorotic new leaves. (Fig. 21)
Excessive calcium results in reduced magnesium uptake, with the symptoms
related to magnesium deficiency.
Figure 21:
Characteristic calcium (Ca) deficiency symptoms
Magnesium
As magnesium is a key element in photosynthesis, its rate slows down
under conditions of magnesium deficiency, resulting in Reduced tuber formation
and lower yields. Severe magnesium deficiency can reduce yields by up to
15%. Magnesium-deficient tubers are more easily damaged during lifting
and storage.
Typical deficiency symptoms: Leaves get yellow and brown; The leaves
wilt and die; Stunted plants, early crop maturation; Poor skin finish of the
tubers. (Fig. 22)
Excessive magnesium results in reduced calcium uptake, with the symptoms
related to calcium deficiency.
Figure 22:
Characteristic magnesium (Mg) deficiency symptoms
Sulfur
Sulfur (S) deficiency causes reduced growth, and leaves become pale
green or yellow. Number of leaves is reduced. (Fig. 23)
Figure 23:
Characteristic sulfur (S) deficiency symptoms
Iron
Under Iron (Fe) deficiency, the interveinal areas get chlorotic while
the veins remain green. In cases of severe deficiency, the entire leaf is
chlorotic. (Fig. 24). Iron deficiency symptoms firstly appear on the youngest
leaves.
Figure 24:
Characteristic Iron (Fe) deficiency symptoms
Boron
Boron (B) regulates transport of sugars through membranes, and also
plays a key role in cell division, cell development and auxin metabolism.
Under condition of boron deficiency growing buds die, and plants appear
bushy, having shorter internodes. Leaves thicken and roll upward; leaf tissue
darkens and collapses. Brown necrotic patches appear on tubers, and internal
rust spot are formed. (Fig. 25)
Figure 25:
Characteristic Boron (B) deficiency symptoms
Copper
Under copper (Cu) deficiency young leaves become flaccid and wilted,
terminal buds drop at flower bud development, and leaf tips become necrotic
(Fig. 26).
Figure 26:
Characteristic Boron (B) deficiency symptoms
Zinc
Zinc deficiency symptoms: Young leaves become chlorotic (light green or
yellow), narrow, upwardly-cupped and develop tip-burn. Other leaf symptoms are
green veins, spotting with dead tissue, blotching, and erect appearance. (Fig.
27)
Figure 27: Characteristic
Zinc (Zn) deficiency symptoms
Manganese
Manganese (Mn) deficiency symptoms: black or brown spots on younger
leaves; leaves yellowing; poor skin finish of the tubers (Fig. 28). Tubers are
more easily damaged during lifting and storage.
Figure 28:
Characteristic manganese (Mn) deficiency symptoms
Table 8: Reference
levels for each nutrient at foliar level:
|
Nutrient (%) |
Deficient |
Low |
Normal |
High |
Excessive |
|
Nitrogen (N) |
4.2 |
4.2-4.9 |
5.0-6.5 |
>6.5 |
|
|
Phosphorus (P) |
0.23 |
0.23-0.29 |
0.3-0.55 |
>0.6 |
|
|
Potassium (K) |
3.3 |
3.3-3.9 |
4.0-6.5 |
6.5-7.0 |
>7.0 |
|
Calcium (Ca) |
0.6 |
0.6-0.8 |
0.8-2 |
>2.0 |
|
|
Magnesium (Mg) |
0.22 |
0.22-0.24 |
0.25-0.5 |
>0.5 |
|
|
Sulfur (S) |
|
|
0.30-0.50 |
|
|
|
Nutrient (ppm) |
Deficient |
Low |
Normal |
High |
Excessive |
|
Copper (Cu) |
3 |
3.0 -5.0 |
5.0 -20 |
30-100 |
|
|
Zinc (Zn) |
15 |
15-19 |
20-50 |
|
|
|
Manganese (Mn) |
20 |
20-30 |
50-300 |
700-800 |
>800 |
|
Iron (Fe) |
|
|
50-150 |
|
|
|
Boron (B) |
15 |
18-24 |
30-60 |
|
|
|
Sodium (Na) |
|
|
0-0.4 |
>0.4 |
|
|
Chloride (Cl) |
|
|
0-3.0 |
3.0-3.5 |
>3.5 |
2.5 Plant nutrient requirements
Table 9:
Nutritional requirements of potatoes
|
Expected yield
(ton/ha) |
Removal by yield
(kg/ha) |
Uptake by whole
plant (kg/ha) |
||||||||
|
N |
P2O5 |
K2O |
CaO |
MgO |
N |
P2O5 |
K2O |
CaO |
MgO |
|
|
20 |
38 |
18 |
102 |
2 |
2 |
105 |
28 |
146 |
29 |
19 |
|
40 |
76 |
36 |
204 |
4 |
4 |
171 |
50 |
266 |
42 |
28 |
|
60 |
114 |
54 |
306 |
6 |
6 |
237 |
72 |
386 |
55 |
37 |
|
80 |
152 |
72 |
408 |
8 |
8 |
303 |
95 |
506 |
68 |
46 |
|
100 |
190 |
90 |
510 |
10 |
10 |
369 |
117 |
626 |
82 |
55 |
|
110 |
209 |
99 |
561 |
11 |
11 |
402 |
128 |
686 |
88 |
59 |
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