Herbicide Residue Causes and Management PDF

Summary

This document discusses herbicide residue causes and management in soil encompassing various factors. It details soil factors including physical, chemical, and microbial aspects, as well as climatic conditions affecting herbicide degradation. Herbicide properties are also examined.

Full Transcript

HERBICIDE RESIDUE CAUSES AND
THEIR MANAGEMENT
The quantity of herbicide that remains in soil after its mission is
accomplished is referred as residue. The term residue infers the
continued presence of herbicide in the soil in very small quantities even
though it may not be present in herbicidal quantities or available for
plant absorption. Herbicide residues in soils are undesirable mainly
because they may:
1. Injure sensitive crops in a cropping system,
2. Be absorbed by succeeding crops and residues accumulated in
unlawful amounts in the produce,
3. Inhibit in build-up of herbicide residues following repeated
treatments that exceed their rate of dissipation, and
4. Inhibit growth of soil microorganisms.

FACTORS AFFECTING HERBICIDE
PERSISTENCE
Factors that influence herbicides persistence are:
Soil Factors
The soil factors affecting herbicide persistence fit into 3 categories:
physical,chemical, and microbial. Soil composition is a physical factor
that measures the relative amounts of sand, silt and clay (the soil texture)
and the content of the soil. Chemical properties of the soil include pH,
organic-matter cation-exchange capacity (CEC), and nutrient status. The
microbial aspects of the soil environment include the type and
abundance of soil microorganisms present composition affects herbicide
phytotoxicity and persistence through adsorption, leaching and
volatilization or both have a greater potential for herbicide carry over

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because there is increase absorption to soil colloids, with a
corresponding in leaching and adsorption volatilization. This ‘tie-up
results in initial plant uptake and herbicidal activity. Therefore, more
herbicide is held in reserve to be released later, potentially injuring
susceptible future crops.
Some herbicides, principally the triazines (atrazine and simazine), at
particularly influenced by soil pH, an important part of the soil chemical
maken Lesser amounts of these herbicides are adsorbed or held to soil
colloids at higher soil pH, so they remain in the soil solution. Herbicides
in the soil solution a available for plant uptake. Chemical breakdown
and microbial breakdown-2 major herbicide degradation processes are
often slower in soils of higher pit So although decreased adsorption of
triazine herbicides occurs in soils having higher pH, there is also less
breakdown activity. Therefore, these herbicides are more available for
plant uptake for a longer period on soils of higher pH. Certain members
of the sulfonylurea group (chlorsulfuron and chlorimuron) can also
persist in higher pH soils because rates of chemical breakdown are
decreased Low pH affects the persistence of clomazone and the
imidazolinones (imazaqun and imazethapyr). Soil pH has little effect on
the persistence of other herbicides
Research shows that various nutrients and cations in the soil impact both
herbicide activity and degradation. The CEC, principally a function of
clay type and organic matter content, is directly involved in herbicide
adsorption. Some herbicides are more available in the presence of
certain cations, whereas others may be tied up and therefore unavailable.
The literature indicates that there is much variation in the effect that
cations and nutrients can have on herbicide activity and breakdown,
depending on soil composition, nutrient type and concentration, and
chemistry of the herbicide.
Soil microorganisms are partially responsible for the breakdown of
matny herbicides. The types of microorganisms and their relative

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amounts determine how quickly decomposition occurs. Soil microbes
require certain environmental conditions for optimal growth and
utilization of any pesticide. Factors that affect microbial activity are
temperature, pH, oxygen and mineral nutrient supply Usually, a warm,
well-aerated, fertile soil with a medium soil pll is most favourable for
microorganisms and hence herbicide breakdown.

Climatic Conditions
The climatic variables involved in herbicide degradation
are moisture, temperature and sunlight. Rates of herbicide
degradation generally increase with increased temperature
and soil moisture because both chemical and microbial
decomposition rates increase under conditions of higher
temperature and moisture Cool, dry conditions slow
degradation, causing greater carryover potential. If winter
and spring conditions are wet and mild, herbicide
persistence is less likely. Sunlight is another important
factor in herbicide degradation. Photo- degradation, or
decomposition by light, has been reported for many
herbicides. The dimitroanilines (trifluralin and
pendimethalin) are sensitive to light degradation. May be
lore degradation applied if they remain for Mahal
Therefore, degradation is accelerated on very sunny days.
This sensithour light and loss by volatility are primary
reasons for soil incorporationer
Herbicidal Properties

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Finaly, the chemical properties of a herbicide affect its persistence.
Important factors are: water solubility, soil adsorption, vapour pressure
and susceptibility to chemical and microbial alteration or degradation.
The water solubility of a herticide helps determine its leaching potential.
Leaching occurs when a herbicide dissolved in water and moves down
through the soil profile. Herbicide that readily leaches may be carried
away or carried to rooting zones of susceptible plants. Herbicide
leaching is determined not only by water solubility of herbicide. But also
by its ability to adsorb to soil particles. Additionally, soil texture and
available soil water affect herbicide leaching. Herbicides that are low in
water solubility, are strongly adsorbed to soil colloids, and exist in dry
soils are less likely to leach and have a greater potential to persist. The
vapour pressure of a herbicide”determines its volatility, the process of
changing from a liquid or a solid to a gas. Volatility increases with
temperature. Volatile herbicides such as the thiocarbamates (EPTC,
butylate) must be incorporated immediately to avoid gaseous losses.
These herbicides are less likely to persist than herbicides with low
vapour pressures. Herbicides may be rapidly decomposed by
microorganisms in the soil if the numbers of microorganisms are present
and if soil conditions are favourable for their growth. However,
herbicides vary greatly in their susceptibility to microbial
decomposition. For example, microbial degradation of 2,4-D occurs very
quickly in the soil, whereas microbial degradation of atrazine is slow.
Chemical decomposition is dependent not only on the chemistry of the
herbicide (how susceptible it is to chemical breakdown) but also on soil
and climatic factors. Chemical breakdown of a herbicide involves
reactions such as hydrolysis, oxidation and reduction. The occurrence of
these reactions and the rates at which they take place vary with soil type
and climatic conditions. These reactions, along with microbial
degradation, are important processes in the decomposition of herbicides.

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Management of Herbicide Residues in Soils
Various management techniques have been developed to minimize
residue hazards in soils:
Use of optimum dose of herbicides
Trifluralin @ 0.72 and 0.96 kg/ha to soybean leaves exhibits no adverse
residual effect on succeeding wheat, but @ 1.2 kg/ha the wheat will be
affected.
Application of farmyard manure
Residues of atrazine @ 0.5 kg/ha applied to pearlmillet [Pennisetum
glaucum (L.) R. Br.] affect subsequent greengram and cowpea.
However, an application of FYM @ 12 t/ha to pearlmillet can mitigate
the residual toxicity of atrazine.
Cultural practices
These include ploughing and intercultivation. Residual toxicity of
propyzamide, trifluralin and atrazine can be considerably brought down
by ploughing.
Crop rotation
Residues of herbicides applied to preceding crop should not be toxic to
the succeeding crop in rotation. Application of atrazine to maize, diuron
to cotton and chloramben to soybean does not exhibit direct or residual
effect on succeedingcrops in cotton-maize-soybean rotation. Application
of diuron @ 1.0 kghate cotton will not injure oat and wheat grown in a
rotation.

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Use of non-phytotoxic oil and activated carbon
Atrazine residual hazard can be decreased by mixing it with non-
phytotoxs oil. Activated carbon shows high adsorptive capacity due to its
tremendous surface area.

Use of herbicide safeners or antidotes
Safeners can protect the crop from possible damage by a herbicide. R-
25788 marketed as a mixture with EPTC and butylate for soil
application and naphthalic anhydride (NA) is used for seed dressing on
rice to protect the crop against molinate and alachlor. Another safener
cyometrinil is used along with metolachlor in crop of grain sorghum.
Leaching of soil
Herbicide residues can be removed by leaching.
Trap-crop approach
One obvious answer to herbicide-residue problems in sul ist
deliberately include crop plants in rotation that are resistant to a
particular Berbicide. This permits the land to stay in production and at
the same time, it hastens the dissipation of the herbicide. Such crops are
called herbicide-trap crops eg sugarcane, sorghum and maize, are good
trap crops for eliminating residues of arazine and simazine from soil.
Crop breeding for selecting crop

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