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Field Problems and their Solutions in Kharif Rice Production
In securing optimum yields from high yielding varieties
of rice specific diagnosis of field problems and adoption of good management
practices is the best solution apart from breeding suitable varieties
and judicious plant protection. The following are some of the field management
problems and solutions in kharif rice production.
1) Selection of suitable variety
Mashuri, the popular local variety, is tall growing and
susceptible for lodging and kharif pest complex.
it is usually caught in rains at maturity and germinates
institute. Available high yielding varieties without these two bad characters
should be selected depending on the agroclimatic situation.
2) Field problems in the nursery
i) Prefer certified seed from a recognised source.
Ensure seed treatment before sowing. Examine whether nursery was sown
thin to obtain sturdy and healthy seedlings. Densely sown seedbeds tend
to give weak and lanky seedlings which are prone to get transplanted in
bunches, leading to delayed establishment and low tillering and give scope
for excessive weed growth. Broadcasting on a drained bed @ 50-70grams
of seed per square metre (depending on seed size and germination) is ideal.
ii) Wetland seed beds that have been just sown
Check for smooth level, evenness of sowing and depth of
sowing. Puddle should settle down for a day prior to sowing of sprouted
seeds. The seed should just sink in the bed and not buried. Unevenness
of levelling results in suppression of germination both in high and low
level areas and leads to patchy nursery. If the nurseries are patchy and
gappy, inspite of proper levelling, and management of water, the problem
might be either due to bad seed or improper broadcasting of seed.
iii) Seed bed after 8-10 days of sowing
In dry seed beds check the seedlings whether they are normal
green or turning pale and white. In black soils with high pH or lime content
and in red soils with low organic matter, dry nurseries are liable to
be affected by iron chlorosis.
In the region comprising Guntur, Prakasam and Nellore districts
chlorosis in rainfed rice and upland nurseries is common. This may be
due to iron or manganese deficiencies or both. In both the cases interveinal
chlorosis in the young leaves can be seen.
In the case of iron deficiency spray 0.5% Ferrous Ammonium
or Ferrous Sulphate (5 grams Ferrous sulphate or Ferrous ammonium sulphate
plus 0.75 grams citric acid per litre of water) repeatedly at 4 to 5 days
interval till the chloratic leaves turn normal green.
iv) Wet land seed bed ready for uprooting within 5-6 days
Pullout a few and check the seedlings. They should have
4-6 leaves and this is the optimum stage for transplanting seedlings.
This stage is reached in 20-25 days in summer and kharif and 30-40 days
in cool weather in Rabi.
Remember that physiological age is more important than chronological
age.
Seedlings should not be pale yellow in colour, which indicates
N deficiency. Arrange for application of N at 0.3 to 0.6kg N per 100 square
metres six days before pulling the seedlings in the form of a quick acting
fertilizer like urea. If transplantation is expected to be delayed, let
seedlings remain yellow and postpone fertilization until a week before
transplantation. Seedlings should not exhibit leaf lodging which indicates
over management of seed bed. No further application of N should be suggested
in such cases.
v) Seed bed ready to uproot
The seed bed should be flooded a day earlier so as
to prevent root damage while uprooting. Some damage to roots may be inevitable.
If the soil is heavy the damage to root system is likely to be more. This
may be overcome by adopting a high seed rate. Careful uprooting not only
minimises gap filling but also helps quick establishment and improved
tillering. If the soil of seed bed tends to be sticky, advise incorporation
of paddy husk to facilitate easy uprooting of seedlings or else the stickiness
may form clumps and cause breakage at the collar.
Uprooting should be preferably done in the evenings and
should be transplanted withint 24 hours. They should not be allowed to
wilt in any case.
vi) Overaged seedlings
When seedlings are overaged potential for tillering is reduced,
specially with short duration varieties than late maturing ones.
To compensate loss in tillering recommended closer, planting
and heavier fertilisation. Minimise nursery fertilisation.
3) Management in Main field :
i) Main field ready for transplantation:
Thorough puddling is essential to reduce excessive water
percolation and loss of applied fertilizer due to leaching and easy transplantation.
This should be done 2 to 3 weeks before transplantation (specially in
cooler season) to save seedlings from the harmful effects of decomposing
organic matter applied.
Allow 3 weeks time for decomposition of green leaf manures
if puddled in wetlands, keeping them submerged under water. Level the
field uniformly after puddling.
Advise the farmers to keep the field flooded from first
ploughing to transplanting time. Otherwise nitrogen will be lost due to
denitrification.
The common mistake in the case of black soils is to transplant
without allowing the puddle to settle. In a freshy puddled field planting
tends to be deep resulting in low tillering. Advise the farmers to allow
the puddle to settle for two days before transplanting. In the case of
red soils the farmers can rush to transplant or else the puddle settles
down and makes transplantation difficult later.
If the field is not evenly levelled the transplanted seedlings
may sink at lowest place. The water and nitrogen management will be very
defective and the crop will not grow uniformly.
ii) Is algae a problem in the area?
In such cases skip or minimise basal N dose or delay by
10 days. Keep the water at minimum level till the seedlings are established.
In severe cases apply 1 to 2 kg copper sulphate per hectare mixed with
sand. Dry the field alternatively by which algae would settle down and
turn brown.
iii) Zinc deficiency
If the crop is not thriving inspite of proper fertilization,
if it is patchy and unhealthy the problem is most likely zinc deficiancy.
Zinc sulphate at 50kg/ha once in three seasons is the general recommendation.
In saline and alkali soils zinc deficiency is more serious than in normal
soils. In such soils zinc sulphate is to be applied every year.
Do not mix zinc sulphate with phosphate fertilizers. Apply
them separately with 2-3 days gap.
iv) Mainfield planted the previous day:
The seedlings should be planted shallow i.e., not more than
3cm deep. Deep planting results in delayed establishment and results in
poor tillering and yield.
In case the total N proposed is 80-100kg per hectare, spacing
should be 20x15cm. If the seedlings are over aged or fertilization is
medium level or if the varieties are low tillering close spacing of 15x10cm
can be adopted.
Planting of more than 2 seedlings per hill is not desirable.
Advise the farmers to reserve some seedlings in the nursery
for gap filling.
v) Mainfield ten days after planting
Establishment of the plant is indicated by the resistance
offered when pulled. Advise farmers to keep not more than 2-3 cm film
of water.
Gap fill twice, once 7 days after planting and second time
within 10 days after planting. Loss of production is more serious than
disturbance to plants due to gap filling.
vi) Main field 20 days after planting
There should be 200 tillers per square metre in a field
where 20x15cm spacing is adopted i.e., 6 tillers per hill under good management.
Check for nitrogen, phosphate, potash deficiency, sulphide injury, salinity
and alkalinity problems and correct them.
For BPH prone areas and the succeptible varieties recommend
planting of seedlings 30cm in rows apart which may help in minimising
BPH incidence. This further makes easy the spraying of insecticides.
vii) Water Management:
Keep water not more than 5cm deep throughout tillering period
i.e., upto 45 to 55 days after planting and at 5cm from P.I to flowering.
Never dry or drain the field except to top dress fertiliser. Avoid continuous
flow of water in the belief that water should be periodically changed.
A field flooded with a thin film of water would retain available soil
nitrogen in a stable ammoniacal form. If the field is subject to drying
and reflooding, soil nitrogen would be oxidised into nitrats and lost
by leaching during subsequent flooding. Therefore alternate drying and
wetting causes significant loss of nitrogen leading to poor growth of
crop.
viii) Fertilizer Management
In delta areas fertilizer doses should be determined based
on soil test results.
Split application of N have proved to be far better as the
efficiency of applied N with split application is above 30% under transplanted
conditions. Extra yield of 13% in Kharif and 23% in Rabi have been recorded
due to split application.
In NSP area P2O5 has to be applied
at a higher dose. In canal areas of Nellore district nitrogen has to be
applied at the rate of 40kg N/ha as the response is very poor.
ix) Main field 50 days after planting
Tillering would have been nearly complete. Check there should
be 350-400 effective tillers per square metre.
x) Main field at flowering
Examine whether there is protracted flowering. If so this
may be due to retarded growth, delayed top dressing, improper spacing,
deep planting etc. Advise the farmer to adopt proper management practices
in the next season.
4. Harvesting
High yielding varieties maintain greenness due to their
habit of slow senescence. Do not wait till the crop is completely dry.
Harvest when the stems are green (karra patchi) stage. This will avoid
grain shattering and also breakage in milling. Breakage in milling is
the result due to hasty over drying rather than a varietal characteristic
etc.
5. Save Paddy caught in rains with salt treatment
Harvested sheaves with panicles if dipped in 5% salt solution
prevents grain germination and spoilage of straw. If threshed paddy can
be heaped on straw in a place with slope and 4kgs salt can be sprinkled
for every 100 kg paddy, prevents grain germination. Thus every quintal
paddy can be saved from spoilage with only two rupees.
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Field Problems
