INTRODUCTION
Sorghum plays an important
role in the development and evolution
of dedicated energy crops. This work focuses
on sorghum growth and
development, composition, relevant production issues and varieties. As an
energy crop, sorghum is unique
in that there
several types of
sorghum that are
and can be used biofuel and
bioproduct production,with the
defining factor in
these crops being
the primary source
of carbohydrates.
Sorghum (sorghum bicolor (L)moench)
is an indigenous
crop to Africa
, and though commercial
needs and uses
may charge over
time, sorghum will
remain a basic
staple food for
many rular communities.
The latter is especially true
in the more
drought prone areas of South Africa where
this crops provide better household food
security than maize.
Sorghum
is mainly cultivated
in drier areas,
especially in shallow
and heavy clay soil.
The production of sorghum
in South Africa varies
from 100,000 ton (13,000 ha to
180,000 ha) per annum. The
free state and
Mpumalanga provinces are the largest contributors to
the area planted to n Sorghum
and Sorghum production.
In
recent years, there has
been a shift
in Sorghum production
from the drier
western production areas
to the wetter
eastern areas. This
change has resulted
in the identification and
development of cultivars
which are more
tolerant to lower
temperature.
SORGHUM CULTIVATION
Sorghum is a cultivated grass
native to sub-saharan
Africa, several varieties
of which are
widely grown for
the grain, as
forage, as a
source of syrup.
Sorghum
belongs to the grass
family, Graminea. It is essential
that producers know
the crop they
are cultivating in
order to develope the
most effective production
practices.
planting sorghum
Planting
time usually varies
from September to
January , depending on planting
rain and soil
temperature early in the season. Crop
failures are likely
in central and
southern regions from very
early plantings in
August - September and very
late plantings in
February- March due to
cold conditions. Planting
at the early
end of the
range is preferred to
avoid midge bproblems
and to
allow the option
to double-crop a
winter crop if
sufficient rainfall is
received. Best yields
usually follow October
plantings. These crops
usually miss insect
damage by midge.
With late crops, midge resistant
sorghum hybrids and/or with
the use of
insecticide sprays. Generally, mid-season hybrids
are the best
over all performance. Sorghum ergot
disease risk can
be minimized by
planting from mid-October
to mid-January in
southern Queenland so
that flowering occurs
between mid-January to
mid-March when the
probability of ergot
developing in sorghum
florets is lowest.
Plant population
DRYLAND
Expected yields
largely determine the population required. Lower populations are required
in the marginal areas and high populations where conditions are good.
Planting population - dryland
Yield expectation(t/ha)
|
Plant/ha
|
1-3
|
30000-50000
|
3-5
|
50000-75000
|
5-7
|
75000-150000
|
Quick-maturing
hybrids planted in good conditions require higher plant populations than
slower
hybrids to realise the yield potential for a particular environment.
IRRIGATED
In irrigated crops, the choice of target plant
population is dependent on row spacing.
Increase
populations to 150,000-200,000 plants/ha for partial irrigation, or
220,000-250,000
for full
irrigation.
Planting population - irrigated
Row
spacing (m)
|
Plants/ha
|
0.15-0.30
|
250,000
|
0.75
|
150,000
|
1.0
(single rows)
|
120,000
|
1.0
(twin rows)
|
200,000
|
Average seeding rate
·
Dryland 3-4 kg/ha
·
Irrigated 10
kg/ha.
The rate
depends on seed size, target population, expected establishment and germination
percentage.
How to
calculate planting rate (kg/ha)
Planting
rate = Target population (plants/ha) x100 x 100
No. of seeds/kg x
expected field establishment (%) x germination (%)
No of
seeds/kg = 28,000 (depending on variety, marked on bag)
Germination
% = marked on bag
Expected
field establishment (depending on insects, seedbed, machinery):
Precision planter 70-80%
Airseeder (press wheels) 50-70%
Airseeder (no press wheels) 40-60%
Row spacing
·
25 cm optimum for
yields exceeding 4 t/ha.
·
50 cm for
expected yields of 3-4 t/ha.
·
75 cm for
expected yields of 1-3 t/ha.
Under
good growing conditions, narrow rows out-yield wide rows. This advantage
decreases
as soil moisture
reserves decline. There may be situations where it is necessary to row crop
even though
expected yield indicates narrow rows are superior (e.g. where inter-row
cultivation
is used for weed control).
In dry
areas where yields are less than 1.0 t/ha, the row spacing may be as wide as 2m.
Depending
on the planter, twin rows spaced 18-45 cm apart with wide centre give a less
cramped
spatial arrangement of seedlings and have regularly shown yield benefits.
Seed placement depth
50-75 mm
into moisture. It is only necessary to plant seed deep enough to
give it
moisture to germinate and allow its roots to grow down through moist soil into
subsoil moisture,
ahead of the drying front.
Suitability for zero tillage
Sorghum
is the most widely grown zero tillage summer crop in the Burnett. It tolerates
compacted
subsoil and can stand high presswheel pressure at planting. Good grass control
in the crop
is essential to achieve high yields but this can be expensive with herbicides.
Some
farmers are now using shielded sprayers and knock down herbicides prior to
planting.
The
longer the paddock is under zero tillage the easier it is to establish the
following crops.
GROWTH AND
DEVELOPMENT
The growth and development
of sorghum are divided into the vegetative and reproductive growth stages
Vegetative
growth stages: Identification of the sorghum growth stage
during vegetative growth is done according to leaf development.
Reproductive
growth stages: The identification of
the reproductive growth stage is done according to the development of grain
kernels.
GROWTH
REQUIREMENTS AND ADAPTATION
The optimum growth requirements of sorghum plants, in
order to exploit its inherit yield potential, are a deep well-drained fertile
soil, a medium to good and fairly stable rainfall pattern during the growing
season, temperate to warm weather (20 – 30 °C) and a frost-free period of
approximately 120 to 140 days.
Soil
requirements
Sorghum is mainly grown on low potential, shallow
soils with high clay content, which usually are not suitable for the production
of maize. Sorghum usually grows poorly on sandy soils, except where a heavy
textured subsoil is present. Sorghum is more tolerant of alkaline salts than
other grain crops and can therefore be successfully cultivated on soils with a
pH (KCl) between 5,5 and 8,5. Sorghum can better tolerate short periods of
waterlogging compared to maize. Soils with a clay percentage of between 10 and
30 % are optimal for sorghum production.
Climatic
requirements
The climatic requirements for the production of
sorghum are divided into temperature, day length and water needs.
Temperature
Sorghum is a warm-weather crop, which requires high
temperatures for good germination and growth. The minimum temperature for
germination varies from 7 to 10 °C. At a temperature of 15 °C, 80 % of seed
germinate within 10 to 12 days. The best time to plant is when there is
sufficient water in the soil and the soil temperature is 15 °C or higher at a
depth of 10 cm. Temperature plays an important role in growth and development
after germination. A temperature of 27 to 30 °C is required for optimum growth
and development. The temperature can, however, be as low as 21 °C, without a
dramatic effect on growth and yield. Exceptionally
high temperatures cause a decrease in yield.
Day length
Sorghum is a short-day plant, which means that the
plant requires short days (long nights) before proceeding to the reproductive
stage. The optimum photoperiod, which will induce flower formation, is between
10 and 11 hours. Photoperiods longer than 11 to 12 hours stimulate vegetative
growth. The tropical varieties are usually more sensitive to photoperiod than
the quick, short-season varieties. Sorghum plants are most sensitive to
photoperiod during flower initiation.
Water requirements
Sorghum is produced in South Africa on a wide range of
soils, and under fluctuating rainfall conditions of approximately 400 mm in the
drier western parts to about 800 mm in the wetter eastern parts.
FERTILISATION
To assess the
correct quantity of fertiliser to be
applied for optimal yield, soil samples should be taken according to the
recommendations of an accredited soil laboratory.
Fertiliser recommendations made according to the soil
analysis should be applied accordingly.
Symptoms of
deficiencies that may be observed in the field are as follows:
·
Nitrogen (N)
deficiency—young plants are light green or yellow- green, at a more mature
stage the older leaves start yellowing first, with a characteristic inverted
V-shape.
·
Phosphorus (P)
deficiency—under wet, cool conditions leaves of young plants may turn dark
green with reddish-purple margins and tips.
·
Potassium (K)
deficiency—a deficiency of K is initially noted as yellow or necrotic leaf
margins, beginning at the lower leaves and spreading to the upper leaves.
WEEDS
Weed control during the first 6 to 8 weeks after
planting is crucial, as weeds compete vigorously with the crop for nutrients
and water during this period. The root parasite Striga asiatia (L.) Kuntze or witchweed (rooiblom) can damage the crop and mainly occurs under low input
farming conditions. The parasitic plants are single stemmed with bright red
flowers. Most of the damage is done before the parasite emerges from the soil.
The symptoms include leaf wilting, leaf rolling, and leaf scorching even though
the soil may have sufficient water. The tiny seeds are disseminated by wind,
water and animals, and remain viable in the soil for 15 to 20 years. rotation
with cotton, groundnut, cowpea and pigeonpea will reduce the incidence of Striga. Hand pulling the plants before
flowering may be useful.
MARKETING,
USES AND PRODUCTS
Grading
For grading
purposes sorghum is divided into the following classes:
Class GM: This includes malt sorghum that does not have a dark
testa (condensed tannins), is listed as a GM cultivar and meets the
requirements of Class GM sorghum as stipulated by the grading regulations.
Class GL: This includes sorghum which does not have a dark
testa (condensed tannins) and is from a GM cultivar that cannot be graded in
the Class GM sorghum or from a GL cultivar as stipulated in the cultivar list,
and meets the requirements of Class GL sorghum as stipulated by the grading
regulations.
Class GH:This includes malt sorghum which has a dark testa
(condensed tannins) and is from a GH cultivar as determined by the cultivar
list, and meets the requirements of Class GH sorghum as stipulated by the
grading regulations.
Other
sorghum:This includes sorghum which
does not meet the requirements of Class GM, Class GL and Class GH sorghum.
Sorghum
products for the consumer
Malt: Commercial malt is produced from GM cultivars with
specific character- istics. Industrial malt is produced from GM and GH
cultivars. Condensed tannins in GH cultivars are neutralised before malting
commences. The malt is used in the industrial production of sorghum beer.
Beer: Preparation of beer is a lengthy process covering 3
days. Ingredients for the preparation of beer are malt, meal and yeast.
Beer powder: Instant beer powder is a premixed product that
consists mainly of sorghum malt, a starch component and brewers yeast. A
24-hour period is needed before the beer can be consumed.
Sorghum meal:
Sorghum meal, also known as Mabele,
directly competes with maize meal. Sorghum with condensed tannins is not used
for meal production .
Sorghum rice: Sorghum rice or corn rice is whole, decorticated
sorghum.
Livestock
feed: and other animal products
Livestock feed is the most important market for surplus sorghum, as it competes
effectively with other grain products in terms of price and quality. Sorghum is
an important component in poultry feed and good progress has been made in the
manufacturing of dog food, as well as pigeon and ostrich
food
SORGHUM
VARIETIES
Scientific
classification
Kingdom:Plantae
order:Poales
Family
:Poaceae
Sub-Family:Panicoideae
Tribe:
Andropogoneae
Genus: Sorghum
Species:
sorghum bicolor
The genus
sorghum is divided into five sections: Parasorghum,
Stiposorghum, Heterosorghum, Chaetosorghum and Sorghum.
Parasorghum: Sheath-nodes densely bearded, pedicillate spikelets
staminate, panicle branches simple, awn and callus well developed, chromosomes
large, n=5.
Stiposorghum: As Parasorghum except awn and callus better
developed, n=5.
Heterosorghum: Pedicellate spikelets reduced to glumes, panicle
branches divided, awn and callus poorly developed, chromosomes medium, n=10 or
20.
Chaetosorghum: Pedicellate spikelets reduced to glumes, panicle
branch simple, awn well developed, callus poorly developed, chromosomes medium,
n=10 or 20.
Sorghum: Sheath-nodes glabrous or finely pubescent, not
bearded, pedicellate spikelet staminate, panicle branches divided, awn and
callus poorly developed, chromosomes medium, n=10.
Section Sorghum includes annual cultivated forms from
Asia and Africa and perennial taxa from southern Europe and Asia.
Three species are recognized:
•S. halepense (L.) Pers. (2n=40): A rhizomatous perennial species
with creeping rhizomes, pedicellate spikelets deciduous when mature, and up to
25 cm long.
•S.
propinquum (Kunth) Hitchc (2n=20): A
rhizomatous perennial species with creeping rhizomes, pedicelled spikelets deciduous
when mature, sessile spikelets acute to acuminate, lower glume with the keels
ending without or with only obscure teeth, leaf blades broad, panicles large,
and 20–60 cm long.
•S. bicolor (L.) Moench:
annual taxa cultivated.
Species S.
bicolor comprises three subspecies:
bicolor, drummondii and
verticilliflorum.
•Subsp.
bicolor: Plants annuals, with stout
culms, often branched, frequently tillering, leaf blades up to 90 cm long and
12 cm wide, inflorescence open or contracted panicle, branches often several
from lower nodes, obliquely ascending or spreading, racemes tough.
•Subsp. drummondii: Plants annual with
relatively stout culms, leaf blades lanceolate up to 50 cm long and 6 cm wide,
panicles rather contracted, branches somewhat pendulous, racemes more or less
crowded, mostly 3-5 noded, tardily disarticulating at maturity.
•Subsp.
verticilliflorum: Plants tufted
annuals or weak biannual, leaf blades linear-lanceolate up to 75 cm long and 6
cm wide, panicles usually large, somewhat contracted to loose with branches
obliquely ascending or spreading, racemes 1–5 noded, fragile.
The cultivated
sorghums (Sorghum bicolor Subsp. bicolor)
were classified into five basic races
•Bicolor: Grain elongate, sometimes slightly obovate, nearly
symmetrical dorso-ventrally, glumes clasping the grain, which may be completely
covered or exposed as much as ¼ of its length at the tip, spikelets persistent.
•Guinea: Grain flattened dorso-ventrally, sublenticular in
outline, twisting at maturity nearly 90 degrees between gaping involute glumes
that are from nearly as long to longer than the grain.
•Caudatum: Grain markedly symmetrical, the side next to the
lower glume flat or in extreme cases somewhat concave, the opposite side
rounded and bulging, the persistent style often at the tip of a beak pointing
towards the lower glume, glumes ½ the length of the grain or less.
•Kafir: Grain approximately symmetrical more or less
spherical, glumes clasping and variable in length.
•Durra: Grain rounded obovate, wedge-shaped at the base and
broadest slightly above the middle; glumes very wide, the tip of a different
texture from the base and often with a transverse crease across the middle.
These five basic races and ten intermediate
combinations can account for all the variation in the cultivated forms.
CONCLUSION
sorghum is an
important crop world
wide used for
food(as grain and
in sorghum syrup
and sorghum molasses),
animal folder, the
production of alcoholic
beverages, and biofuel.
Most varieties are
drought and heat
tolerant and are
especially important in
arid region, where
the grain is
one of the
staples for poor
and rural people
. This varieties
form important component
of pastures in
many tropical regions.S.bicolor is
an important food
crop in Africa,central America and South
Asia, and is
the fifth most
important cereal crop
grown in the
world.
REFERENCES
Γ The state of
Queensland (Department of Agriculture
and fisheries) 2010-2015
Queensland
Government.
Γ Sorghum production
- Jean du
plessis
Γ en. m. wikipedia. org/wiki/sorghum.
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