Nano Pesticides and Nanosensors in Agriculture PDF

Summary

This document details the use of nanotechnology in agriculture, focusing on nano pesticides and nanosensors. It explains how these technologies are used to protect crops and detect contaminants. The document also discusses different types of pesticides and how they are used.

Full Transcript

Nano pesticides and nanosensors in agriculture

Pesticides and herbicides are used extensively in agricultural production
throughout the world to protect plants against pests, fungi, and weeds. They
are beneficial in terms of crop protection, disease control, food and material
protection. But at the same time, it is toxic to humans, animals and non-target
species. They have cumulative effects on the human body and lead to several
diseases, ranging from chronic common cough and cold to bronchitis and
cancer of the skin, eye, kidney, and prostate gland.
Pesticides are widely distributed in drinking waters, groundwaters, and soils.
Commonly Used Pesticides:
a) Organochlorine Insecticides: for example, endosulfan, aldrin, and Heptachlor.
b) Herbicides: for example Atrazine, Diuron and Molinate.
c) Organophosphorus Insecticides: for example, Chlorpyrifos and Diazinon.
✓ Pesticides are susceptible to degradation using zero-valent Iron (ZVI).

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Nanopesticids stand for pesticides formulated in nanomaterials to find
applications in the agricultural field, whether specially fixed on a hybrid
substrate, encapsulated in a matrix or functionalized nanocarriers for
external stimuli or enzyme-mediated triggers.
The nanopesticide formulations can increase water solubility, and
bioavailability and protect agrochemicals against environmental degradation,
revolutionizing the control of pathogens, weeds, and insects in the crops.
Nanoparticles have high surface to volume ratio, and they are able to linked
with other compounds and be used as carrier. Hence, they can be used as
nanocarriers or as active ingredients or both.
Nanoformulations usually consist of several surfactants, polymers or
inorganic (e.g. metal) NPs in the nanometre size range.
Nanoparticle-associated pesticides show higher performance in
terms of effectiveness, targeted delivery and action with reduced
management costs.

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A nanocarrier enables the controlled release of an active compound stored
at the core, so that the adequate concentration of this active compound could
be preserved during the whole period of insect growth.

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Contd….

Nanosensors in agriculture: Nanosensors are nanoscale element devices
that are engineered to identify a particular molecules/organisms known as the
analyte and could be molecules (dyes/colours, toxicants, pesticides, hormones,
antibiotics, vitamins, etc.), biomolecules (enzymes, DNA/RNA, allergens, etc.),
ions (metals, halogens, surfactants, etc.), gas/vapour (oxygen, carbon dioxide,
volatile compounds, water vapors, etc.), organisms (bacteria, fungi, viruses) and
environment (humidity, temperature, light, pH, weather, etc.).
A typical nanosensor device operation contains three basic components:
1) Sample preparation
2) Recognition: Certain molecules/elements recognize the analytes within the
sample. They could be antibodies, aptamers, chemical legends enzymes, etc.,
and have high affinity, specificity, and selective characteristics to their analytes
to quantify them to acceptance levels.
3) Signal transduction: for example, optical, electrochemical, piezoelectric,
pyroelectric, electronic, and gravimetric biosensors.

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The component of nanosensors in agriculture

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Contd….

These sensors are highly specific, handy, cost-effective, and detect at a level
much lower as compared to their macroscale analogs.

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Nanosensors for Pesticide Detection

In general, an optical sensor is composed of a recognition element that is
specific for the particular residual pesticidal particle and can network with the
other constituent, the transducer, which is employed to produce the signal for
the binding of a particular pesticide residue to the sensor.
Also, electrochemical nanosensors appear to be an effective tool meant for
pesticide detection. Various categories of nanomaterials comprising
nanoparticles, nanocomposites and nanotubes are widely found to be engaged
in electrochemically determining the residual pesticidal particles.

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Nanosensors for Detecting Plant Pathogens

The most widely used biosensing components for analysing pathogens are
bacterial receptors, antibodies, and lectins, owing to their adaptability of
amalgamation into biosensors.
Nanoparticle-centred “chemical nose” biosensors necessitate the
amendment of the surface of the nanoparticle with several ligands where an
individual ligand is liable for a distinctive communication with the objective.
The mechanism:
The addition of nanoparticles to the bacteria leads to the development of
aggregates encompassing the bacteria. This process of aggregation
promotes a change of colour induced by a swing in localized surface
plasmon resonance. The components of the bacterial cell wall which are
responsible for this kind of aggregation are teichoic acids in Gram-positive
and lipopolysaccharides and phospholipids in Gram-negative bacteria.
These aggregation patterns are unique and are motivated by the occurrence
of extracellular polymeric substances on the bacterial surface. These varying
in patterns are accountable for offering discernible colorimetric responses.

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Nanofertilizers in agriculture
Nanofertilizers are nutrients that are encapsulated or coated within
nanomaterial in order to enable controlled release, and its subsequent slow
diffusion into the soil.
The use of nanoscale fertilizers may help to minimise nutrient loss by
leaching/run-off and reduce its fast degradation and volatility, thus enhancing
the nutrient quality and the fertility of the soil, and promoting crop
productivity in the long run
The high surface area to volume ratio and the high penetration ability of
nanofertilizers make them a suitable alternative to chemical fertilizers.
The composition of nanofertilizers can facilitate:
1. Efficient nutrient uptake and soil fertility restoration.
2. Ultra-high absorption and increased photosynthesis.
3. Increased production and reduced soil toxicity.
4. Increased plant health and reduced environmental pollution.

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Examples of Nanofertilizers:
Nano-Zinc:
Zinc oxide nanoparticles can provide zinc more efficiently to plants,
addressing zinc deficiency in crops.
Nano-Phosphorus:
Phosphorus nanoparticles or nanocarriers can reduce the fixation of
phosphorus in soil, making it more available to plants.
Nano-Nitrogen:
Encapsulation of nitrogen fertilizers in nanoparticles can minimize nitrogen
losses through volatilization and leaching.

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Contd….

https://doi.org/10.1016/j.eti.2021.101658

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Nanosensors for Detection of Heavy Metals

Heavy metal ions like Pb2+, Hg2+, Ag+, Cd2+, and Cu2+ from different resources
have a precarious influence on human beings as well as their surroundings.
Optical chemical sensors that are frequently targeted for heavy metal
detection fit into a cluster of chemical sensors that primarily employ
electromagnetic radiation for engendering a diagnostic signal in an element
known as the transduction element. The interactions between the sample
and the radiation change a specific optical consideration that can be
interrelated to the concentration of an analyte.
Colourimetric approaches are advantageous due to their simple operation,
economically feasible, transportable instrumentation, and easy-to-use
applications.
Several compounds are used for stabilizing nanosensors, such as
polysaccharides citrates, different polymers, and proteins to improve the
attributes of the nanosensors.
Fluorescent quantum dots-based sensors are an efficient tool for sensing
numerous metal ions.

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The introduction of magnetic nanomaterials (Fe3O4) into the quantum dot-
based fluorescence sensors offers several additional advantages owing to their
high specific surface area, special magnetic properties, magnetic operability,
and low toxicity.

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Nanomaterials for air and water pollution
control
The three major applications of nanotechnology in the fields of
environment can be classified:
1) Remediation and purification of contaminated material
2) pollution detection (sensing and detection).
3) pollution prevention.
Air pollution can be controlled with nano-adsorptive
materials, nanocatalysis, and nano filters.
Water pollution, nanofiltration and nano sorbents techniques are used.
Nanotechnology for clean water:
1) Remediation is the process of removing, minimising or neutralising the
water contaminants that can damage human health or ecosystems.
2) Remediation technologies can be divided into three categories, thermal,
physicochemical and biological methods.
3) An advanced method that can be used is nanomaterials, with enhanced
affinity, capacity and selectivity for heavy metals and other contaminants.
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The advantages of using nanomaterials in water
remediation are their higher reactivity, larger surface
contact and better disposal capability.
Water remediation with iron nanomaterial:
✓ Zero valent Iron (ZVI) is classified into two types:
(1) nanoscale ZVI (nZVI) and (2) reactive nanoscale iron
product (RNIP).
✓ nZVI particles have a diameter of 100–200 nm composed
of iron (Fe) with a valence of zero, whereas RNIP particles
consist of 50/50 wt % Fe and Fe3O4.
✓ ZVI has high reactivity to a large number of contaminants,
including Cu2+, chlorinated hydrocarbons, CrO22- and NO3-.
✓ Nano-iron could be substituted with other metals. Metals
such as zinc and tin have the ability to reduce
contaminants such as iron.

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Water remediation with
ferritin: Iron stored inside protein
✓ Ferritin is an iron-containing protein
that is able to control the formation of
mineralized structures. Ferritin has
the ability to remediate toxic metals
and chlorocarbon un.
✓ The advantages of ferritin over
ordinary iron catalysts are:
(1) ferritin does not react under
photoreduction; and visible light or
solar radiation
(2) it is also more stable.

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Nanotechnology in water pollution treatment

The major mechanisms used to remove contaminants from contaminated water
through nanotechnology include nanofiltration and nano-sorbents.
Nanofiltration:
1. Nanofiltration is a membrane process used
in water pollution treatment for drinking
water and wastewater.
2. Nanofiltration is a low-pressure membrane
technique used to separate substances
measuring 0.001-0.1 micrometre.
3. Nanofiltration is an effective method used
to remove biological pollutants, turbidity,
and inorganic compounds. Also, to soften
hard water, remove dissolved organic
materials, and trace contaminants from
surface water, treatment of wastewater,
and pre-treatment during the desalination
of seawater.
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Contd….
Nano Sorbents:
Nano-sorbents can be used as
separation techniques in the
process of water purification
to eradicate inorganic and
organic matter from
contaminated matter.
Nanoparticles are
effective sorbents due to
their large surface area
and can be enhanced
with different reactor
compounds to improve
their affinity towards
specific compounds.

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Nanotechnology in air pollution treatment

Nanotechnology can be used to treat and remedy air pollution through
strategies such as the use of nano-adsorptive materials for adsorption,
degradation by nanocatalysis, and the use of nano filters to filter and
separate air pollutants.
Use of Nano-Adsorptive Materials to Adsorb Air Pollutants:
✓ Nano adsorbents: carbon nanostructures have high selectivity, capacity, and
affinity due to their physical characteristics, including average pre-diameter,
the volume of the pores, and high surface area.
✓ Nano-adsorbents have unique properties that enable effective interactions
with organic compounds through non-covalent bonds, including hydrogen
bonding, electrostatic forces, hydrophobic interactions, and van der Waal
forces.
✓ Carbon nanotubes have been used as adsorbent materials in environmental
protection because of their characteristics, including high electrical and
thermal conductivity, high strength, the unique potential for adsorption, and
high hardness
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Degradation by Nanocatalysis:
✓ Nanotechnology can be used to prevent air pollution in indoor environments
in a variety of ways. Semiconducting materials photocatalytic remediation is
one effective strategy used to manage indoor pollution through
nanotechnology. Reaction mainly occurs on the active surface, which is the
significant catalyst structure. A decrease in the size of the catalyst leads to an
increase in the surface area to increase the efficiency of the reaction.

✓ Nano-catalysts are considered appropriate materials for improving air quality
and reducing pollutants in the air. For instance, titanium dioxide nanoparticles
have photocatalytic properties to produce self-cleaning coatings used to
decontaminate environmental pollutants, including nitrogen oxides, into
materials that have low toxicity levels. Carbon nanostructures, including CNTs
and graphene nanosheets, have been utilized to increase titanium dioxide’s
photocatalytic effectiveness by facilitating the easy movement of electrons.

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Use of Nano Filters for Separation and Filtration Purposes:
✓ Nano filters are structured membranes with small pores to separate several
contaminants from the exhaust to control air pollution by capturing gas
pollutants.
✓ Filter media coated with
nanofiber is mainly used in
industrial plants to remove dust
and filter the inlet air for gas
turbines.
✓ Silver and copper
nanoparticle filters are
extensively used in air filtration
technology as antimicrobial
agents for the removal of
biological aerosols such as
viruses, bacteria, and fungi that
cause infections.
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Classes of nanomaterials in the removal of
organic pollutants from environment
Nano-photocatalysts: The term ‘‘photocatalysis’’ refers to
the processes where light is used to excite the photocatalyst
and accelerate the rate of the reaction, in which the
photocatalyst remains unaltered.
Nano photocatalysts are photocatalysts with 1 nm and 100 nm
of size, in the presence of light, can accelerate the reactions.
Nano-sized metals, zero-valent forms, monometallic oxides,
bimetallic oxides, semiconductors can be used for the
degradation of contaminants in the wastewater such as organic
dyes or heavy metal ions.

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Nanophotocatalysts are highly capable of enhancing the
mineralization of highly toxic and complex organic substances
even at 25 ℃.
These nano-sized materials are highly effective in mineralizing
and degrading a wide range of organic Contaminants.
In mineralization, the complex organic pollutants were
decomposed into simpler compounds, whereas the
decomposed compounds were completely destructed in the
degradation stage, resulting in the formation of much simpler
compounds like H2O, CO2.

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Contd….
Water and Air remediation using nanosize semiconductor
photocatalyst:
Examples of photocatalysts:
1. Titanium dioxide (TiO2)
2. Zinc oxide (ZnO)
3. Iron oxide (Fe2O3)
Photocatalysts are able to oxidize organic pollutants into nontoxic materials.
The advantage of using Titanium dioxide (TiO2) for water remediation:
1. low toxicity.
2. high photoconductivity.
3. high photostability.
4. Excellent chemical and biological stability.
5. easily available and inexpensive materials.
The advantage of using ZnO for water remediation:
ZnO photocatalysts are able to detect and remediate contaminants from water.
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Contd….

Nano and micromotors:
A typical nano-motor is a
nano-scale device which is
having the ability to convert
energy into movement.
The nano-motors are capable
of generating the forces in the
order of few piconewtons.
The important aspects of nano
and micromotors are their
high operational speed,
movement specificity, and
ability to self-mix.
Micro/nanomotors are
environmentally friendly and
have attractive power units.

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