Our soil is one of the most prominent reasons that life is possible on this planet.

By definition, soil is a particulate surface material made up of various minerals as well as organic matter.

Soil supports and nourishes plant and animal life by providing it with nutrients.

The ancients changed their fates and ours when they evolved from hunter-gatherers to cultivators of the land.

Over time, our chemistry with soil has evolved and helped form the foundation of our thriving civilization on this planet.

From tiny unicellular algae to complex vascular plants, almost all flora need soil for their development.

All soils present on Earth are a mix of three components: clay, silt, and sand.

These components directly reflect soil properties such as water-holding capacity and nutrient levels, and play a crucial role in agricultural practices.

It is necessary for any farmer to take into account soil composition to ensure successful yields.

Understanding soil also helps a farmer choose the right irrigation system for his crops.

For example, loam, the most fertile soil type, contains approximately equal proportions of clay, silt, and sand.

It has better water holding capacity with an optimum aeration rate as well as high nutrient composition, all essential to healthy plant growth.

On the other hand, sandy soil has high aeration, and water drains through very easily.

Clay is made of fine particles and has a greater surface area.

Soil with a higher percentage of clay has higher water holding capacity, and excessive water supply leads to accumulation of water at the roots.

All soils in the world contain two types of mineral content.

Primary minerals directly reflect the parent material from which the soil is formed, such as calcium, iron, magnesium, and silica.

On the other hand, secondary minerals are the result of the weathering of primary minerals.

They are responsible for the release of several ions as well as stabilising the mineral form.

The mineral content of the soil varies by geography.

For instance, red soils from the Western Ghats contain high quantities of iron oxides, whereas soils in the Ganga basin are rich in silicates.

Along with minerals, organic content is another crucial component of healthy plant growth.

Dead animals and plants, as well as animal faecal matter, are the highest contributors to organic content in the soil.

Soil rich in organic content is best for agriculture as it supplies crops with essential elements such as nitrogen, sulphur, and carbon.

Organic content also holds moisture and keeps roots hydrated.

• Read: Microbes: Invisible Superheroes

Soil nurtures our agriculture, and agriculture sustains and defines our lives by providing food.

However, agriculture is often disruptive to natural ecosystems, as not all soils are suitable for farming.

The need to alter and enhance the soil to increase yield led to the invention and use of synthetic fertilisers.

Their rampant, injudicious, and improper use has led to a global crisis of soil infertility as well as disturbed and damaged ecosystems all over the world.

Microorganisms like bacteria, protozoa, and fungi are the microflora of the soil.

They reside in the soil and use organic matter and minerals present in the soil as their food.

These microorganisms are fully equipped with biochemical factories that carry out various actions to nourish crops.

Let’s take the example of nitrogen fixation. Our atmosphere is made up of 78 percent Nitrogen.

Nitrogen is also present in all living forms, starting from our genetic makeup to amino acids.

Despite being composed of nitrogen, no animal or plant can consume atmospheric nitrogen directly.

Atmospheric nitrogen first needs to be fixed in the soil, where it starts its journey through our ecosystems and into our food.

Microorganisms fix the nitrogen in soil by converting it into nitrates and then nitrites, which are consumed by plants.

Nitrogen-fixing bacteria or fungi are present in the soil in two forms: free-living and symbiotic association with plant roots.

Free-living bacteria like Azotobacter do not require a host to fix nitrogen.

On the other hand, symbiotic bacteria shelter in plant roots, forming a nitrogen-fixing structure.

Symbiotic bacteria like Rhizobia are mainly present in leguminous plants.

Rotational crop systems involved cultivating leguminous plants as they restored nitrogen used up by the previous crop, maintaining the nutrient balance in the soil.

Along with nitrogen, phosphorus is the second key element essential for plant development.

In the early stages of plant growth, an adequate supply of phosphorus is crucial for the development of the reproductive parts of plants.

Phosphorus strengthens plants by providing vitality and disease resistance as it is responsible for root ramification.

It also regulates seed formation and maturation in cereals and legumes.

A deficiency of Phosphorus stunts plant growth.

Though present in abundance in soil, in organic and inorganic forms, its availability is limited due to its insoluble nature.

Several bacterial, actinomycetes, and fungal species can solubilise phosphorus present in the soil.

Solubilised phosphorus is a bioavailable form that facilitates uptake by plant roots.

The temperature, as well as the presence of other nutrients such as nitrogen and oxygen, greatly influence the phosphate-solubilising ability of these microorganisms.

• Also Read: Can microbes enhance the health of animals in your poultry farm?

Along with nutrients and water, crops require plant hormones, including auxins, gibberellins, cytokinins, abscisic acids, and ethylene.

Though plants can synthesize hormones to promote their growth, the amount is often insufficient.

Bacteria, as well as fungi residing in the rhizosphere, also produce plant hormones as their secondary metabolites.

The proximity of these microbes helps plants to absorb the hormones and meet their requirements.

Across the globe, numerous studies and research have been conducted on microbes to use their ability to boost agricultural production.

This research has led to the development of bio-fertilisers and bio-pesticides used in sustainable farming practices.

Judicious use of these eco-friendly agricultural products has the potential to take our planet farther along the path to food safety.

Bio-fertilisers are formulations made of live bacteria or fungi.

These organisms are plant-specific, and their targeted actions on specific plants supply them with required nutrients as well as hormones.

Unlike synthetic nitrogen and phosphate fertilisers, bio-fertilisers do not cause any harm to the soil.

After four decades of the Green Revolution, chemical fertilisers and their salts have accumulated in the soil, resulting in increased alkalinity and acidity.

Bio-fertilisers like MagicGro DripSol can not only boost plant growth but also restore land quality.

They contain denitrifying bacteria, which reverse the effects of nitrogen leaching.

Urea, one of the most prominently used chemical fertilisers, resulted in excessive nitrogen in the soil.

Denitrifying bacteria use ammonia and its salts and convert them into gaseous nitrogen that is released into the air.

By reducing the nitrogen load in the soil, they reverse chemical pollution, allowing plants to grow and flourish in healthy soil.

Bio-fertilisers come in various forms; farmers can use these fertilisers by either coating them on seeds or directly applying them to the soil.

They form a healthy ecosystem with plant roots that help them absorb more nutrients from the earth.

Fungal bio-fertilisers establish mycorrhizal associations with plant roots that maintain moisture and prevent roots from dehydration.

Bio-fertilisers also synthesize products that act as antibiotics against root-invading pathogens, i.e., they provide plant disease resistance.

Along with nutrition, microbes can be used to protect plants from notorious pests, a primary threat to growing crops.

There are instances in history where pests have led to famines in various areas of the world.

There are many reports of pesticide accumulation in rivers and lakes that have damaged local flora and fauna.

DDT, the infamous pesticide used in India, has been responsible for wiping out entire populations of birds and fish.

Some chemical pesticides are mutagens – chemicals that induce tumour formation.

Bio-pesticides have many advantages over chemical pesticides.

They are plant-specific products that contain invasive genes to attack pests.

They are harmless to humans or ecosystems, and their targeted actions bring down pests, leaving the plant to thrive.

Bio-herbicides contain invasive genes that target weeds competing with crops for water and nutrients, ultimately killing them.

Microbes from bio-fertilisers, bio-pesticides, and bio-herbicides are self-replicating.

If we compare the cost of synthetic products used every season to that of bio-products, there is no contest.

Bio-products win hands down.

We often hear our grandparents talk about how vegetables used to be tastier when they were children.

They aren’t wrong. Synthetic fertilisers and pesticides are stripping our crops and vegetables of their natural taste!

Imagine a world where everything tastes bland.

Don’t we, and generations to come, deserve to experience the genuine taste of nourishing food, just as our grandparents did?

If this is the future we want, then microbial technology is our answer.

Plus, using microbial technology to sustain agricultural production is by far the most befitting response to nature’s abundant generosity and one to which she is truly entitled.

Hydroponics is a new method of farming where plants are grown without using the traditional medium of soil.

With hydroponics, nutrient management becomes exact & efficiently managed.

Hydroponic farming requires less space, conserves water, and uses fewer resources.

The control over nutrition ensures the quality remains the best.

For large-scale farming of this type, the initial cost for set-up is high, but it eventually breaks even easily.

When individuals or nearby farms adopt hydroponic farming, it highlights the urgent need for a sustainable agriculture system that will benefit future generations.

The COVID-19 pandemic has restricted food supply and created a need for nations to move towards self-sufficiency in terms of food.

Hydroponic farming can be used to overcome a food crisis.

As the system is controlled, fresh produce is possible throughout the year, and this negates the effect of bad weather conditions.

Another highlight of hydroponic farming is that custom hydroponic nutrient solutions can be made as per the needs of the plant.

Generally, it contains nitrogen, potassium, magnesium, and secondary nutrients like calcium, sulphur, phosphorus, and micronutrients like zinc, copper, and manganese, all necessary for the growth of plants.

While it is possible to grow any vegetable hydroponically, root development of plants, size, and sturdiness will require better structure and systems.

At the same time, a growth medium will be required to promote plant growth in a water-based solution.

Ensuring the right mix of high-quality hydroponic nutrients is essential for increased productivity.

The use of plant growth-promoting bacteria has been reported to greatly enhance the quality as well as productivity of hydroponically grown plants.

You can use Organica Biotech’s MagicGro DripSol, which contains plant growth-promoting bacteria.

It ensures optimal nutrient uptake by plants, maintains leaf chlorophyll content, and repels harmful bacteria, thus improving immunity against diseases and increasing the flowering and growth rate of plants.

Plus, it is completely natural and safe to use for farming and gardening purposes in households and farms.

To elevate your hydroponic farming and gardening, MagicGrow DripSol is the ideal solution.

Rice is one of the most important staple crops in the world, providing nourishment to millions of people. However, rice cultivation is also one of the most water-intensive crops, accounting for about 40% of global irrigation water use. This makes it essential to adopt sustainable water management techniques in rice cultivation.

In this article, we will discuss some of the most effective water management techniques in rice cultivation, including both traditional and modern methods.

Traditional Water Management Techniques

1. System of Rice Intensification (SRI): The System of Rice Intensification is a sustainable method of rice cultivation that relies on a set of practices designed to increase crop productivity while minimizing the use of water, fertilizer, and other resources. SRI involves transplanting single seedlings at wider spacings, maintaining soil moisture through intermittent irrigation, and minimizing the use of chemical fertilizers and pesticides.
2. Alternate Wetting and Drying (AWD): AWD is a water-saving technique that involves intermittently flooding and draining the rice fields. The method allows the soil to dry out between irrigations, which reduces water usage while maintaining optimal growing conditions for the rice plants.
3. Flood Tolerant Varieties: Certain varieties of rice are better adapted to growing in waterlogged conditions. These flood-tolerant varieties can withstand longer periods of flooding and require less water than traditional rice varieties.

Modern Water Management Techniques

1. Irrigation scheduling: Precision irrigation scheduling involves the use of sensors and other technologies to monitor soil moisture levels and weather conditions. This allows farmers to apply water only when and where it is needed, reducing water usage and improving crop yields.
2. Laser land leveling: Land leveling using laser technology is a modern technique that helps to improve water use efficiency in rice cultivation. The method involves using laser-guided equipment to level the rice fields, which allows for more precise water application and better crop growth.
3. Rainwater harvesting: Rainwater harvesting is a technique that involves collecting and storing rainwater for use in rice cultivation. The method can be used to supplement irrigation water and reduce the amount of water needed for rice cultivation.

Benefits of Sustainable Water Management Techniques in Rice Cultivation

1. Increased crop productivity: Sustainable water management techniques, such as SRI and AWD, have been shown to increase crop yields while reducing the amount of water used in rice cultivation.
2. Reduced water usage: Adopting sustainable water management techniques can significantly reduce the amount of water used in rice cultivation, helping to conserve this precious resource.
3. Lower greenhouse gas emissions: Sustainable water management techniques can help to reduce greenhouse gas emissions associated with rice cultivation, such as methane emissions from flooded rice fields.
4. Improved soil health: Sustainable water management techniques, such as precision irrigation scheduling and laser land leveling, can help to improve soil health and fertility, which can lead to better crop yields over time.
5. Cost savings: By reducing the amount of water and other resources used in rice cultivation, sustainable water management techniques can also lead to cost savings for farmers.

Organica Biotech offers a range of sustainable and innovative solutions for rice cultivation that can add significant value to the industry. Here are a few key ways in which the products and services can benefit rice farmers:

1. Enhanced Root Development for Efficient Water Uptake
   Organica Biotech’s solutions promote deeper and denser root systems. With a greater root surface area, plants can absorb water more efficiently from the soil, reducing the need for frequent irrigation. 
2.  Improved Soil Structure and Water Retention
   Our unique  microbes enhance the soil biofertility and structure. This leads to better water infiltration and retention in the root zone. As a result, water remains available to plants for a longer duration, reducing surface runoff and lowering irrigation frequency.
3. Increased Drought Resilience Through Microbial Action
   The beneficial microbes in Organica Biotech’s formulations support plants in activating natural drought-tolerance mechanisms. They stimulate the production of plant hormones and bioactive compounds that help crops cope with water stress. This microbial support means that even under limited water availability, plants stay green, vigorous, and productive.
4. Compatibility with Modern Water-Saving Practices
   Organica Biotech’s solutions work synergistically with techniques like the System of Rice Intensification (SRI), laser land leveling, and precision irrigation. When used together, farmers can achieve water savings significantly without compromising on yield. These practices, powered by microbial support, make agriculture more resilient and resource-efficient in the face of growing water scarcity.

Sustainable water management techniques have become more important than ever before due to growing concerns over water scarcity and environmental degradation. In the case of rice cultivation, it is essential to adopt such techniques to ensure that the crop is grown in a manner that is sustainable and economically viable.

By implementing traditional techniques like the System of Rice Intensification and Alternate Wetting and Drying, farmers can improve crop productivity while minimizing the use of water and other resources. At the same time, modern techniques such as precision irrigation scheduling, laser land leveling, and rainwater harvesting can help to increase water use efficiency, reduce greenhouse gas emissions, and improve soil health.

By choosing Organica Biotech’s sustainable water management solutions, rice farmers can improve their productivity, reduce their environmental footprint, and contribute to a more sustainable future for the industry. With their innovative solutions and technical expertise, Organica Biotech is leading the way towards a more sustainable and productive future for rice cultivation.

Before 12,000 BC, when a climate change event occurred, man was more of a hunter-gatherer.

Farming was ‘invented’ in different places: in West Asia about 12,000 BC, in Africa about 10,000 BC, in South America, and in China about 8000 BC.

From these places, agriculture spread to Europe, northern Europe, Sudan, and Native Americans between 7000 BC and 1 AD.

Early farmers had limited tools.

They made holes in the ground with sticks to plant seeds, pulled weeds by hand, and harvested crops using their bare hands.

Research shows that these early farmers were women, the keepers of seeds.

Around 3000 BC, people began building dams and digging irrigation canals to supply water to areas where rainfall was insufficient for crop growth.

Asian farmers used ploughs pulled by oxen, while in Africa, it was donkeys.

Flint sickles, with little flint triangles, were used to cut the grain for harvesting.

Men now did most of the ploughing and harvesting, and women did the weeding.

Over time, these tools improved – for instance, the harrow in the Middle Ages.

Even the use of the land became more efficient, with farmers employing three-crop rotation to maximize yields from their fields.

In the early 1800s, the invention of the internal combustion engine revolutionized farming.

Powerful machines, such as gas-powered tractors and harvesters, replaced many ploughmen and harvesters, as well as animals.

From this time on, the world witnessed a massive population explosion on a global scale.

With the discovery of antibiotics and vaccines, the mortality rates were lower than ever before.

People were living longer. Agriculture needed to keep up.

They say that necessity is the mother of invention, and our need for more food led to the emergence of a global phenomenon known as the Green Revolution.

In the 1940s, Norman Borlaug developed semi-dwarf, high-yielding, disease-resistant wheat varieties that led to the introduction of these high-yielding varieties combined with modern agricultural production techniques in Mexico, Pakistan, and India.

The crop varieties designed during the Green Revolution were genetically engineered plants.

They were bred primarily in response to the need to improve food security by producing a substantial amount of grain per acre planted.

Synthetic fertilizers, such as urea and potash, were used to protect crops from pests.

These fertilizers solubilized the nutrients, such as nitrogen, potassium, and phosphorus, making them more readily available for crops.

As the rate of action of artificial fertilizers is higher than that of natural processes, this accelerates plant growth.

The production of essential crops, such as wheat, rice, and corn, quadrupled worldwide.

The Green Revolution came to India in the 60s.

The project included planned irrigation of farms, the use of synthetic fertilizers and pesticides, along with the introduction of new high-yielding wheat breeds.

India transformed itself from ‘a begging bowl’ to a ‘bread basket’.

The state of Punjab was the ambassador of the Green Revolution, and to this day, we call the state ‘the granary of India’.

In recent years, an increasing number of experts worldwide have developed divergent views on the success of the Green Revolution and its aftermath.

They assert that in our haste to feed the world, we have inadvertently destroyed the very earth that sustains us.

Dr Vandana Shiva, one of the foremost critics of the movement, says, “The Green Revolution did not save India from famine, as the proponents of Industrial Agriculture and GMO technology would argue; in fact, the Green Revolution reduced India’s production.”

Loss of crop diversity is one of the most disconcerting effects of the Green Revolution.

The Green Revolution strategy mandated planting select breeds of high-yielding crops and phasing out the others.

This has led to a significant loss of crop genetic diversity.

In India, approximately half a century ago, rice farmers cultivated around 30,000 rice varieties.

However, after the Green Revolution, this number significantly decreased, as today, 75 percent of rice farmers harvest only ten rice varieties.

This loss of genetic diversity has been reported worldwide.

• Also Read: Organic farming – Taking a cue from traditional Indian agricultural practices.

Moreover, massive amounts of chemical fertilizers and pesticides were applied to crops to achieve higher yields.

Eventually, the synthetic chemicals began accumulating in the soil, altering its natural texture and disrupting the microbial flora.

Currently, significant agricultural lands in India are experiencing a notable deficiency of essential minerals, including sodium, phosphorus, potassium, zinc, molybdenum, and boron.

There is a significant increase in nitrogen toxicity and heavy metal pollution.

This is particularly alarming, given that in 1905, when Sir Albert Howard was sent to India to introduce chemical fertilizers in farming, upon seeing how fertile the soils were and how there were no pests in the fields, he wrote a treatise called An Agricultural Testament.

This treatise, which has spread organic farming worldwide, was based on India’s ecological farming, now recognized as agroecology – the application of ecological principles to agriculture.

Studies show that 51 percent of all food commodities are contaminated by pesticides, leading to serious illnesses and cancers.

In 2008, researchers at Punjab University detected DNA damage in Indian farmers who used chemical herbicides and pesticides to treat their crops.

A study published by the Postgraduate Institute of Medical Education and Research concluded a direct connection between the emergence of cancer and the use of pesticides in specific regions.

Another study published indicated that health hazards like hypertension, stillborn babies, diabetes, and respiratory illness are all linked to the use of toxic chemicals in pesticides.

An agonising indicator of the situation is “the cancer train”, a train from Bhatinda that carries hundreds of cancer patients and their families to the cancer treatment centre of Bikaner – every day!

Chemical monocultures and commodity production have displaced biodiversity, which is a source of nutrition.

Green Revolution monocultures have destroyed our pulses and oilseeds.

All over the world, we’re seeing a shift toward organic and sustainable farming, which essentially represents a return to traditional farming methods that were the norm before the invention of fertilizers and pesticides.

So what did these ancients know that we have lost along the way?

They depended on tiny, microscopic organisms that were, quite literally, the first dwellers on this planet.

Yes, I’m talking about microbes.

Microbes have pretty much the same effect on the soil as yogurt has on the human body – making it stronger by helping to absorb more nutrients.

Microbes thrive in soil and play an essential role in many of a plant’s biological functions.

They help plants get a good start, secure nutrients, and even help to fend off pests.

The natural benefits of microbes represent the next step in the art of agriculture.

• Read: How technology can make sustainability attainable for farmers

Without the microorganisms in the soil, there would be no plant life, and eventually, no humans on Earth.

Nitrogen is one of the most crucial elements, essential for the growth of every living form on Earth.

Nitrogen is present in the atmosphere in the gaseous form.

However, neither plants nor animals can directly consume this nitrogen, but microbes can.

Bacteria, such as Nitrosomonas and Azotobacter, reside in soil and fix atmospheric nitrogen, making it available to other living organisms.

Like nitrogen, there are multiple elements, such as phosphorus, potassium, zinc, etc., which are fixed by microorganisms present in the soil.

This community of millions of microbes residing in the soil is called the agribiome.

Thousands of interdependent bacteria and fungi make a healthy agribiome.

Microbes establish symbiotic associations with plants, benefiting from each other in the process.

They colonise roots and help plants to absorb more nutrients through their decomposing actions.

Certain fungi, by residing at the roots, maintain moisture and, therefore, protect them from drying.

In return, plants provide shelter as well as their waste products, which microbes use as food.

In simplest terms, sustainable agriculture is the production of food, fiber, or other plant or animal products using farming techniques that protect the environment, public health, human communities, and animal welfare.

This form of agriculture enables us to produce healthy food without compromising the ability of future generations to do the same.

Sustainable farms produce crops without relying on toxic chemical pesticides, synthetic fertilizers, or genetically modified seeds.

They rely on traditional agricultural principles, such as crop rotation and the use of organic waste, as well as harnessing beneficial microbes (bio-fertilisers and bio-pesticides).

These farming methods strictly forbid the use of any synthetic material and, therefore, contribute to maintaining soil fertility and ecological balance.

In a way, sustainable farming is aimed at keeping the soil alive and letting nature do what it does best.

Sustainable farming utilizes bio-fertilizers composed of crop-specific bacteria that aid crops in absorbing both available nutrients in the soil and those in the air.

They allow farmers to minimise the use of chemical fertilisers and preserve the quality of the land for future generations.

With the help of nature and every farmer’s not-so-secret superstar, microbes, sustainable farming gives us food that has higher nutritional value compared to that from modern farming.

It is the only way to sustain the Earth for future generations.

The world’s population is increasing, and so is the need to feed the population.

Seeds provide nutrition and protection to the embryo.

The growth and development of the plant as a whole depend upon the performance of the seed.

The yield, performance of the plant, and its resistance to undesirable parameters depend upon the emergence and germination rate of the seed.

Seeds are powerhouses of nutrition, which makes them perishable.

Various biological, physical, and chemical parameters affect the performance of both the seed and the seedlings.

As we know, seeds are rich in nutrition, which makes them susceptible to various biological flora, including bacteria, fungi, pests, insects, and nematodes.

Physical parameters, such as dust & temperature, also affect the seeds. High temperatures cause seed desiccation, which affects the embryo.

To generate a healthy quantity and quality of food crops, the health of the seeds needs to be taken into consideration.

What is Seed Coating?

Seed coating technology involves the technique in which seeds are supplemented with various materials, including nutritional elements, plant growth regulators, chemicals, and pesticides, to improve seed vigor by adding an adhesive substance.

Various natural and synthetic polymers can be used as adhesives for coating seeds.

Natural polymers, such as cellulose, Chitosan, Acacia gum, and Starch, can be used.

Synthetic polymers, such as polyethylene glycol, Polyvinyl acetate, and polyvinylpyrrolidone, can be used in seed coating technology.

A slurry is created, which is used for coating the seed, consisting of a polymer (adhesive), antifungal and antibacterial agents (protection against pathogenic bacterial and fungal cultures), Color (for improving aesthetic value), and Plant growth hormones (auxin and cytokinin as plant growth regulators).

• The advantage of this seed coating technology is that the seed’s quality is not compromised by any external factors.
• Disadvantages include uneven coating and thickness of the seed coat, which can hinder emergence and germination rates.

The solution to this problem can be filming the materials.

Seed filming is a technique in which the slurry is sprayed onto the seeds as they flow through or are dropped into an automated machine.

A thin layer of required material is coated onto the seeds by spraying, using the seed filming technique.

The polymer used in this technique dries quickly; therefore, the seeds can germinate through the dry polymeric coating after sowing.

Seeds, when treated with various materials, can help improve the performance prior to sowing.

An environmentally safer way to use insecticides, pesticides, and fertilizers is through seed coating, as the quantities required are in very small amounts.

Seed coating technology does not hamper the genetic makeup.

Therefore, this technique is a far more farmer-friendly & environment-friendly way to improve the yield and quality of crops.

Organica Biotech utilizes seed coating technology to develop advanced, environmentally friendly, and sustainable products that promote agricultural growth.

Also Read:

• Paving The Way For Sustainable Agriculture with Biological Seed Treatment
• Microbes: Every Farmer’s Not So Secret Superstar

India is one of the world’s largest cotton producers, ranking second after China.

The country has been producing cotton for textiles for many years.

Today, approximately 5.8 million farmers earn a living from growing cotton fields, with ten million people employed in the cotton industry.

Climate change, water scarcity, and poor soil quality pose significant challenges to cotton farming in India.

Cotton in India also faces pest pressures due to climate change.

While pink bollworm infestations decreased by 70% in 2018-19 compared to the previous season, pressure from other common pests remained similar to that of previous years.

With increased pesticide resistance in some regions, there is a knock-on effect on yields in other regions.

Farmers do everything they can to protect their crops, but lack knowledge of best practices in managing pests.

They tend to use pesticides regularly or opt for harmful chemicals.

This puts their health at risk and damages the environment.

Some of the major cotton-sucking pests that affect cotton yield are:

• Cotton Aphids
• Cotton Thrips
• Cotton Leafhoppers
• WhiteFly

Let’s understand their characteristics and how they affect cotton crops.

Cotton Aphids

Cotton aphids are mainly seen on the underside of leaves and shoots of the younger cotton plant.

The cotton aphid can be winged or wingless. Its color varies from pale yellow to black-green.

• How Does It Affect the Cotton Crop?

It affects the crop by leaving behind white skin remnants. It extracts the nutrients of the plant, thereby affecting plant growth.

Cotton Thrips

Thrips are also known as early-season pests of cotton. They have pierce-sucking mouths and are straw-colored insects.

• How Does It Affect the Cotton Crop?

They directly attack the leaves and leaf buds, causing silvering on the lower leaf surface.

Heavy infestation of cotton thrips can delay fruiting and maturity.

Cotton Leafhoppers

Leafhoppers have wings held rooflike over the abdomen. They are pale green to yellowish green in color with slender legs. They suck sap from the cotton plant.

• How Does It Affect the Cotton Plant?

Leafhopper infestations cause discoloration and leaf curl; the outer zone of the leaf turns yellow to reddish and white later on.

Heavy leafhopper infestation may retard plant growth and cause severe yield losses.

WhiteFly

Whiteflies, also known as snow flies, are tiny sap-sucking insects found on the underside of the leaves.

They resemble tiny moths and are covered in powdery white wax.

• How Do They Damage the Cotton Plants?

They suck the juice or produce a sticky substance known as honeydew, on which sooty mold develops.

This affects the plant’s photosynthetic activities and, in turn, leads to poor quality and low yields.

After understanding the characteristics of cotton-sucking pests and their effects on the cotton crop, let us learn different ways to eliminate them.

One of the most common approaches farmers use is the use of pesticides.

Farmers use pesticides to protect cotton crops from damage. However, this practice has many disadvantages.

To better understand the pros and cons, it is essential to know how pesticides affect crops and farmers, as well as how to protect them from pests.

Pesticides and Crop Protection

With many pests and weeds attracted to cotton, it is essential to protect the crop from damage.

Pesticides are the primary form of crop protection consumed worldwide.

While they control pests and safeguard yields, we must also consider the negative consequences that are present.

Around 44% of farmers are poisoned by pesticides every year.

They cause serious health issues like cancer and neurological diseases.

It also has long-lasting environmental impacts.

The chemicals present in the pesticides can pollute water sources and even contaminate food supplies.

Looking at the side effects of pesticides, how can farmers protect their crops from unwanted pests and weeds?

Cotton farmers can adopt a holistic approach to crop protection by seeking sustainable options that benefit not only the farm workers and the farming community but also the environment.

With our microbiome technology, which harnesses the power of nature, we at Organica Biotech have developed a technology that enhances nutrient uptake in cotton and improves resistance to pests and diseases.

Our plant biostimulant products contain a unique consortium of plant growth-promoting microorganisms that help farmers take that next step towards sustainable farming by reducing the need for chemical inputs in the soil and crops.

Our technology is designed to increase productivity in an ecologically and sustainably responsible manner, thereby protecting our precious natural resources for future generations.

Our range of plant biostimulant products features natural biostimulants that can be utilized in both organic and non-organic farming practices, serving as effective soil conditioners.

With this innovation, we helped many farmers across the country overcome crop damage and increase their yield.

Are you using chemical pesticides as a preventive measure to ensure disease-free cotton fields?

Contact our experts today at ex*****@*************ch.com.