Chapter 12 of 12

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IB Class 9 Science★ 6–8 marks · CBSE Class 9 board (Unit V — Food Production)

Improvement in Food Resources

India feeds 1.4 billion people from limited land. Class 9 Improvement in Food Resources covers crop variety improvement, fertilisers vs manure, irrigation, cropping patterns, organic farming, animal husbandry (cattle, poultry, fish, bees), and 20+ exam-style problems with full step-by-step solutions.

⏱ 40 min readEasy difficulty✓ Free · NCERT-aligned

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By the end of this chapter you'll be able to…

1List the factors that improve crop varieties (yield, quality, resistance, adaptability, agronomic traits)
2Distinguish hybridisation, selection, genetic modification, and mutation breeding
3Compare manure and chemical fertilisers on five features (nutrient content, soil structure, release rate, cost, environmental impact)
4Distinguish mixed cropping, intercropping and crop rotation
5Name kharif and rabi crops; explain why crop rotation includes legumes
6List traditional and modern irrigation methods; choose appropriate techniques for different soils
7Identify common pests (locust, aphids, stem borer) and diseases (rust, blight, mosaic virus) and their control methods
8Describe the practices of cattle farming, poultry farming, fish farming and apiculture in India

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Why this chapter matters

India's food security depends on the science covered in this chapter. With 1.4 billion mouths to feed on shrinking arable land, every student needs to understand HOW we grow food and what the trade-offs are between yield, sustainability, and environmental health.

Before you start — revise these

A 5-minute refresher here will save you 30 minutes of confusion below.

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The Fundamental Unit of Life (Class 9 Ch5)

Basic cell biology helps understand plant nutrition and animal physiology.

Improvement in Food Resources — Class 9 (CBSE)

India produces ~ 320 million tonnes of food grains a year, feeding 1.4 billion people. That's roughly 700 g of grain per person per day — and it comes from agricultural land that's been shrinking for decades. This chapter is about how Indian agriculture meets the challenge: better crop varieties, smarter farming techniques, dairy and poultry industries that now supply 25% of India's gross agricultural output.

1. The story — Green Revolution to Sustainable Agriculture

In 1960, India imported much of its wheat. Famine was an annual threat. By 1980, India was self-sufficient. By 2024, India is the world's largest exporter of rice and second-largest of wheat.

This transformation — the Green Revolution — was led by Indian agricultural scientists (M.S. Swaminathan, B.P. Pal) and Norman Borlaug. Key levers:

High-yield variety (HYV) seeds.
Fertilisers and pesticides at scale.
Irrigation expansion.
Mechanisation.

But the Green Revolution also created problems: soil degradation, groundwater depletion, pesticide pollution. Today's challenge is the Evergreen Revolution: produce more food with less land, water, and chemicals — sustainably.

This chapter is your introduction to the science behind both eras.

2. Crop variety improvement

Modern agriculture starts with the SEED. A good crop variety has:

High yield — more grain/fruit/vegetable per hectare.
Improved quality — better protein, oil, vitamin content.
Biotic resistance — to pests (insects, nematodes) and diseases (bacteria, fungi, viruses).
Abiotic resistance — to drought, salinity, waterlogging, heat, cold.
Wider adaptability — performs across regions and seasons.
Desirable agronomic traits — short stature (less wind damage), early maturity (more crops per year), responsiveness to fertiliser.

Methods to improve a crop variety

(a) Hybridisation — cross two genetically different parents to combine desirable traits.

Intervarietal: cross two varieties.
Interspecific: cross two species (e.g., wheat × rye → triticale).
Intergeneric: cross two genera.

(b) Genetic modification (GM) — directly introduce desirable genes from any organism. Example: Bt cotton (carries a Bacillus thuringiensis gene for pest resistance).

(c) Selection — repeatedly pick the best individuals over generations.

(d) Mutation breeding — induce mutations (chemical, radiation) and select beneficial ones.

Examples of HYV varieties

Wheat: Sonalika, Kalyan Sona (Green Revolution mainstays).
Rice: Pusa Basmati 1, IR-8 (the "miracle rice").
Pulses: PDM-54 (mung bean), KWR-30 (lentil).

3. Cropping patterns — getting more from the same land

How a farmer arranges crops in time and space affects yield, soil health, pest pressure.

(a) Mixed cropping

Two or more crops grown SIMULTANEOUSLY on the same land. Reduces risk: if one crop fails, the other survives. Example: wheat + mustard, soybean + maize.

(b) Intercropping

Two or more crops in DEFINITE ROW PATTERNS. Better than mixed cropping for harvesting and fertiliser management. Example: maize + soybean rows alternating; turmeric + maize.

(c) Crop rotation

Different crops grown in succession on the same land across seasons. Key benefits:

Different crops use different soil nutrients — prevents single-nutrient depletion.
Legumes (pulses) fix atmospheric nitrogen via root bacteria — restore soil N for the next crop.
Breaks pest cycles.

Example rotation: rice → wheat → mungbean → rice (over 2 years).

(d) Seasonal cropping in India

Kharif crops: sown in June (monsoon), harvested in October. Examples: rice, maize, soybean, cotton, groundnut.
Rabi crops: sown in November, harvested in March-April. Examples: wheat, gram, peas, mustard.

4. Nutrient management — manure vs fertilisers

Plants need 16 nutrients. Macronutrients (large amounts): N, P, K, Ca, Mg, S. Micronutrients (small amounts): Fe, Cu, Zn, Mn, Mo, B, Cl. Carbon, Hydrogen, Oxygen come from air and water.

Manure

Decomposed plant + animal waste.
Rich in organic matter; provides N, P, K + micronutrients (in small amounts).
Improves soil texture, aeration, water retention.
Releases nutrients SLOWLY (over months).
Made on the farm — cheap, sustainable, environmentally friendly.

Types: compost, vermicompost (using earthworms), green manure (plough a young leguminous crop back into the soil).

Fertilisers

Manufactured (chemical) — concentrated single or multiple nutrients.
Three main types:
- Nitrogen fertilisers: urea, ammonium sulphate. ~46% N in urea.
- Phosphorus fertilisers: superphosphate, DAP.
- Potassium fertilisers: muriate of potash (KCl).
Released quickly → fast plant growth.
Used in HYV cropping where soil natural fertility cannot keep up with high-yield demand.

Why combine both?

Property	Manure	Fertiliser
Nutrient content	Low % (~1-2%)	Very high (~46%)
Soil structure	Improves	Doesn't (may degrade with overuse)
Release	Slow	Fast
Cost	Cheap	Expensive
Environmental load	Low	High (runoff causes eutrophication)

Best practice: integrated nutrient management — manure to build long-term soil quality, fertiliser to give the boost a high-yielding crop needs.

5. Irrigation — water management

India is monsoon-dependent: ~70% of annual rainfall in 4 months. Without irrigation, only one crop per year is possible in most regions.

Sources of irrigation

Wells (open and tube wells) — ~ 60% of irrigated land in India.
Canals — from dams (Bhakra Nangal, Indira Gandhi Canal).
Tanks and ponds — traditional South Indian system.
River lift schemes — pump river water onto fields.

Modern irrigation techniques

Drip irrigation: water drips at the root zone via narrow tubes. Uses 30-70% less water than flooding. Best for water-scarce regions.
Sprinkler irrigation: water sprayed like rainfall. Used for level land with sandy soil.
Furrow irrigation: water flows in narrow channels between rows. Common but wastes water.

Watershed management

Treating water as a community resource — building check dams, rainwater harvesting structures, contour ploughing — to recharge groundwater and prevent floods.

6. Crop protection — pests and weeds

Three classes of threats:

Weeds

Unwanted plants competing for sunlight, water, nutrients.

Examples: Xanthium, Parthenium ("congress grass"), Cyperus.
Control: manual weeding, mechanical (hoe), chemical (herbicides), preventive (clean seeds).

Insect pests

Insects that damage roots, stems, leaves, fruits.

Examples: locust, aphids, stem borer in rice.
Control: biopesticides (Neem oil, Bt spray), chemical insecticides, integrated pest management (IPM).

Diseases

Caused by bacteria, fungi, viruses.

Examples: rust in wheat, blight in potato, mosaic virus in tobacco.
Control: resistant varieties, fungicides, crop rotation.

Storage losses

After harvest, food is lost to:

Rodents (rats, mice).
Insects (weevils in grain).
Fungi (mould).
Moisture (rotting, sprouting).

Modern grain silos with controlled humidity and temperature reduce storage losses from ~ 25% (traditional) to ~ 5%.

7. Animal husbandry — cattle, poultry, fish

Half of Indian food comes from animals (dairy, meat, eggs, fish).

Cattle farming

India has the world's largest cattle population. Two categories:

Milch animals (dairy): cows (Sahiwal, Red Sindhi, Jersey crosses), buffaloes (Murrah).
Draught animals (work): bullocks for ploughing.

Care includes:

Shelter — well-ventilated, well-drained, clean.
Feed — roughage (fibre: straw, hay) + concentrate (grains for energy).
Disease control — vaccinations against foot-and-mouth disease, anthrax, blackleg.
Breed improvement — crossbreeding indigenous + exotic breeds to combine resilience + high yield.

Poultry farming

Eggs and meat (broilers).

Layers = chickens kept for eggs (Rhode Island Red, Leghorn).
Broilers = chickens for meat.
Need temperature-controlled coops, balanced feed (protein 20-25%), vaccination.

Fish farming (aquaculture)

Two types:

Capture fisheries — catching wild fish from sea/rivers.
Culture fisheries — farming fish in ponds.

Composite fish culture: 5-6 species in one pond, each occupying a different ecological niche (surface feeders, mid-water, bottom). Maximises pond productivity.

Bee keeping (apiculture)

Bees produce honey + wax. Pollination of crops is the bigger economic benefit.

Indian bee (Apis cerana indica) — gentle but lower yield.
Italian bee (Apis mellifera) — high yield, used commercially.

8. Sustainable agriculture — the future

Modern challenges:

Soil degradation from over-fertilisation.
Groundwater depletion (Punjab, Haryana water tables falling 1 m/year).
Pesticide pollution.
Climate change affecting rainfall patterns.

Solutions being adopted:

Organic farming: no synthetic fertilisers/pesticides, certified by Indian organic agencies.
Precision agriculture: GPS-guided sowing, satellite monitoring, drone spraying — minimise waste.
Vertical farming: stacked indoor farms with LED lighting, hydroponics. Land-efficient but energy-intensive.
Climate-resilient crops: heat-tolerant wheat, salt-tolerant rice (developed by CRRI Cuttack).
Watershed-based agriculture: holistic management of land, water, vegetation.

9. Closing thought

Agriculture is the only industry on Earth that captures solar energy at scale and converts it into food. India's farmers, working an area smaller than the average American farm's 200+ acres (most Indian farms < 2 hectares), still feed 1.4 billion people.

The science you've learned in this chapter — crop genetics, soil nutrients, water management, animal husbandry — is what makes that possible. The next generation's job is to do it sustainably: producing more from less, while protecting the soil and water for future generations.

The Green Revolution fed India for 50 years. The next 50 years will require an Evergreen Revolution — and you'll be part of designing it.

Key formulas & results

Everything you need to memorise, in one card. Screenshot this for revision.

Plant nutrient categories

Macro: N P K Ca Mg S · Micro: Fe Cu Zn Mn Mo B Cl

Memorise. Macro = >0.1%, micro = <0.1%.

Kharif crops (monsoon)

Rice, Maize, Soybean, Cotton, Groundnut, Sugarcane

Sown June (with monsoon), harvested October.

Rabi crops (winter)

Wheat, Gram, Mustard, Peas, Lentil, Barley

Sown November, harvested March-April.

Composite fish culture

5-6 species in one pond, each at a different niche

Surface feeders + mid-water + bottom feeders. Maximises pond use.

Drip irrigation efficiency

~30-70 % less water than flooding

Critical for water-scarce regions.

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Common mistakes & fixes

These are the exact errors that cost students marks in board exams. Read them once, save yourself the trouble.

WATCH OUT

✗ Saying fertilisers are 'better' than manure unconditionally

✓ They serve different roles. Manure improves long-term soil structure; fertiliser delivers concentrated nutrients fast. Best practice uses BOTH.

WATCH OUT

✗ Confusing kharif and rabi crops

✓ Kharif = monsoon (rice, maize, cotton). Rabi = winter (wheat, gram, mustard). Memorise by season.

WATCH OUT

✗ Calling pulses 'protein sources' only

✓ Pulses are also NITROGEN FIXERS — they have root nodules with Rhizobium bacteria that fix atmospheric N. Crop rotation including pulses naturally enriches soil.

WATCH OUT

✗ Saying organic farming 'has zero pesticide'

✓ Organic farming uses BIOPESTICIDES (Neem oil, Bt sprays, plant extracts) — natural pesticides allowed. The exclusion is on synthetic agrochemicals.

WATCH OUT

✗ Confusing mixed cropping and intercropping

✓ Mixed: seeds mixed and broadcast — no fixed rows. Intercropping: planted in DEFINITE ROW patterns. Row planting helps mechanisation and fertilisation.

WATCH OUT

✗ Saying broilers and layers are the same chickens

✓ Different breeds. Layers (Leghorn, Rhode Island Red) are bred for egg production. Broilers are bred for rapid meat gain — ready for market in 6-8 weeks.

WATCH OUT

✗ Forgetting that Bt cotton is a GM crop

✓ Bt cotton has a Bacillus thuringiensis gene inserted to produce an internal pesticide. Pure genetic modification (GM).

NCERT exercises (with solutions)

Every NCERT exercise from this chapter — what it covers and how many questions to expect.

Section 12.1 (in-text)

Improvement in crop yields; varieties; HYV seeds

Questions

Section 12.2 (in-text)

Cropping patterns: mixed, intercropping, rotation

Questions

Section 12.3 (in-text)

Fertilisers vs manure; integrated nutrient management

Questions

Section 12.4 (in-text)

Irrigation methods and water management

Questions

Section 12.5 (in-text)

Plant protection: weeds, pests, diseases, storage losses

Questions

Section 12.6 (in-text)

Animal husbandry: cattle, poultry, fish, bees

Questions

End-of-chapter

Mixed: classification, terminology, applications

Questions

Practice problems

Try each one yourself before tapping "Show solution". Active recall > rereading.

Q1EASY· Cropping

Differentiate kharif and rabi crops. Give one example of each.

▶ Show solution

Step 1 — Kharif crops.
  Sown in June (with the SW monsoon), harvested in October-November. Examples: rice, maize, cotton, sugarcane, soybean.

Step 2 — Rabi crops.
  Sown in November (after monsoon retreats), harvested in March-April. Examples: wheat, gram, mustard, peas, lentil.

✦ Answer: Kharif crops (June-October, monsoon-dependent) include rice and maize. Rabi crops (November-April, winter cereals) include wheat and gram.

Q2EASY· Manure

Give two advantages of manure over chemical fertilisers.

▶ Show solution

Step 1 — Manure benefits.
  (i) Improves soil texture, water-holding capacity, and aeration — the chemical fertiliser does NOT.
  (ii) Provides organic matter and many micronutrients; sustainable and cheap; environmentally friendly.
  (Also: slow release → less leaching; supports soil microbial life; made locally on farm.)

Step 2 — Choose any two for the answer.

✦ Answer: (i) Improves soil structure and water retention; (ii) provides organic matter + micronutrients sustainably without chemical pollution.

Q3EASY· Crop rotation

Why is crop rotation considered good practice? Give two reasons.

▶ Show solution

Step 1 — Reason 1: Soil nutrient preservation.
  Different crops use different nutrients. Rotating prevents depletion of any single nutrient. Legumes (pulses) actually ADD nitrogen to the soil via root-nodule bacteria (Rhizobium).

Step 2 — Reason 2: Pest and disease management.
  Many pests and diseases are crop-specific. Rotating crops breaks the pest's life cycle — fewer pesticides needed.

  (Also: prevents soil erosion, varies microclimate, allows farmers to manage workload across seasons.)

✦ Answer: (i) Different crops use different nutrients — rotation prevents nutrient depletion. (ii) Crop rotation breaks pest and disease life cycles, reducing the need for pesticides. (Bonus: legumes in rotation fix atmospheric nitrogen and enrich the soil.)

Q4EASY· HYV

What does HYV stand for in agriculture?

▶ Show solution

Step 1 — HYV = High-Yielding Variety.

  HYV seeds are bred (or engineered) to produce significantly more grain per hectare than traditional varieties. They typically require more inputs (water, fertiliser).

✦ Answer: HYV = High-Yielding Variety. Examples: Pusa Basmati 1 rice, Kalyan Sona wheat — backbone of the Indian Green Revolution.

Q5EASY· Animal husb

Give two distinguishing features between layers and broilers.

▶ Show solution

Step 1 — Layers vs broilers.

  Layers: chickens kept for EGG PRODUCTION. Live longer (kept for 18+ months). Examples: Leghorn, Rhode Island Red.
  Broilers: chickens raised for MEAT. Reach market weight in 6-8 weeks. Examples: Cornish Rock, Plymouth Rock crosses.

Step 2 — Highlight two contrasts.

  (i) Purpose: Layers → eggs; Broilers → meat.
  (ii) Lifespan: Layers live 18+ months in production; Broilers slaughtered at 6-8 weeks.
  (iii) Feed: Layers eat balanced feed for egg production; Broilers eat protein-rich feed for rapid muscle growth.
  (iv) Genetics: Layers selected for laying frequency (250+ eggs/year); Broilers selected for fast growth + meat yield.

✦ Answer: (i) Purpose — layers produce eggs; broilers produce meat. (ii) Lifespan — layers kept 18+ months; broilers slaughtered at 6-8 weeks.

Q6MEDIUM· Pest

Name three biotic factors that affect crop yield. Suggest one control method for each.

▶ Show solution

Step 1 — Three biotic factors and their controls.

(i) Weeds (e.g., Parthenium, Xanthium):
  Compete with crops for water, nutrients, sunlight.
  Control: manual weeding, herbicides (chemical), mulching (suppresses weed seedlings).

(ii) Insect pests (e.g., locust, stem borer):
  Eat plant tissues; transmit viruses.
  Control: biopesticides (Bt sprays, Neem oil), chemical insecticides, integrated pest management (IPM).

(iii) Diseases (e.g., wheat rust, potato blight):
  Caused by fungi, bacteria, viruses.
  Control: resistant varieties, fungicides, crop rotation, removing infected plants.

✦ Answer: Weeds (controlled by hand-weeding or herbicide), Insect pests (controlled by biopesticides or chemical insecticides), Diseases (controlled by resistant varieties + fungicides + crop rotation).

Q7MEDIUM· Irrigation

Explain three modern irrigation techniques. Mention which is best for water-scarce regions.

▶ Show solution

Step 1 — Modern techniques.

(i) Drip irrigation:
  Water dripped slowly at the root zone via narrow tubes.
  Saves 30-70% water vs flooding.
  Best for: water-scarce regions, vegetables, fruit orchards.

(ii) Sprinkler irrigation:
  Water sprayed like rainfall through perforated pipes.
  Best for: level land with sandy soil where flooding would cause excessive seepage.

(iii) Furrow irrigation:
  Water flows in narrow channels between crop rows.
  Cheaper than drip or sprinkler but less water-efficient.
  Best for: row crops like maize, cotton, vegetables.

Step 2 — Best for water-scarce regions.
  DRIP IRRIGATION clearly — uses 30-70 % less water than other techniques and delivers water precisely to roots.

✦ Answer: Three techniques: drip (most water-efficient), sprinkler (good for sandy/level land), furrow (cheap, less efficient). Best for water-scarce regions: drip irrigation.

Q8MEDIUM· Nitrogen

Why are leguminous plants (pulses) considered good for soil health? Give two reasons.

▶ Show solution

Step 1 — Reason 1: Nitrogen fixation.
  Roots of leguminous plants have NODULES containing Rhizobium bacteria. These bacteria capture atmospheric N₂ and convert it to ammonia (NH₃) — a form plants can use. The plant uses this nitrogen AND leaves residual nitrogen in the soil after harvest.

Step 2 — Reason 2: Organic matter.
  Leguminous crops contribute organic matter to soil (residues after harvest). This improves soil structure and water-holding capacity.

  Additionally: when ploughed back into soil (as green manure), legumes add a significant boost of organic + nitrogen-rich material.

Step 3 — Practical impact.
  Crop rotation alternating cereal-legume reduces fertiliser N needed by the next crop by 30-50 %. Soil quality improves over years.

✦ Answer: (i) Legumes harbour nitrogen-fixing Rhizobium bacteria in root nodules, enriching the soil with bioavailable nitrogen. (ii) They add organic matter (especially when used as green manure). Both effects make crop rotation including pulses sustainable and economically rewarding.

Q9MEDIUM· Composite fish

What is composite fish culture? Why is it more productive than single-species farming?

▶ Show solution

Step 1 — Definition.
  Composite fish culture = farming 5-6 fish species TOGETHER in one pond, each species occupying a different ecological niche.

Step 2 — Niche assignment (typical).
  • Surface feeders: Catla (eats plankton at surface).
  • Mid-water feeders: Rohu (eats midwater plants/insects).
  • Bottom feeders: Mrigal, Calbasu (eat decaying matter at the bottom).
  • Weed feeders: Grass Carp (eats aquatic weeds).
  • Detritus feeders: Common Carp (eats fish food + waste).

Step 3 — Why more productive.
  In a single-species pond, only ONE feeding niche is exploited; the rest of the pond's resources are wasted. In composite culture, all niches are exploited — pond yield can be 3-5× higher than monoculture.

Step 4 — Practical benefits.
  • Lower per-unit-output cost (no waste of resources).
  • Better pond health (each species' waste is feed for another).
  • Reduced disease risk (species-specific diseases don't spread across species).

✦ Answer: Composite fish culture = 5-6 species farmed together, each at a different feeding niche (surface, mid, bottom). Pond resources are fully utilised, giving 3-5× higher yield than single-species farming.

Q10MEDIUM· Apiculture

Why is bee-keeping commercially important even though honey is just one of its products?

▶ Show solution

Step 1 — Direct products of bee-keeping.
  • Honey (food, medicine).
  • Beeswax (candles, cosmetics).
  • Royal jelly, propolis (health supplements).

Step 2 — Indirect (bigger) economic value: POLLINATION.
  Bees pollinate ~ 75 % of the world's food crops (mustard, apples, almonds, sunflower, cotton, etc.).
  Without bees, these crops would have dramatically lower yields. Some estimates put pollination's value at 20-30× the value of honey production.

Step 3 — Bee-keeping species in India.
  Indian bee (Apis cerana indica) — gentle but lower honey yield.
  Italian bee (Apis mellifera) — commercially used; higher yield.

✦ Answer: Bees produce honey + wax, but their REAL economic value is POLLINATION of crops — ~75 % of food crops worldwide depend on bee pollination. Bee-keeping is essentially an agricultural service industry, not just a honey industry.

Q11HARD· GM crops

What is Bt cotton? Explain its mechanism, advantages, and concerns.

▶ Show solution

Step 1 — Definition.
  Bt cotton is genetically modified cotton that contains genes from the bacterium Bacillus thuringiensis (Bt). The inserted gene codes for a protein called Cry toxin.

Step 2 — Mechanism.
  The Bt cotton plant constantly produces small amounts of Cry toxin in its leaves and bolls. When a target insect (e.g., bollworm, the most damaging cotton pest) eats the plant, the toxin is activated in the insect's alkaline gut, breaks the gut wall, and kills the insect within days.
  Importantly, Cry toxin is INACTIVE in mammalian (acidic) digestive systems, so it doesn't harm humans, livestock, or non-target insects (like bees, ladybugs).

Step 3 — Advantages.
  • 40-50% reduction in chemical insecticide use → environmental benefit + cheaper for farmers.
  • Higher cotton yields → more income.
  • Targeted protection (only against gut-feeding caterpillars).

Step 4 — Concerns.
  • Pest resistance: continuous exposure may lead to Bt-resistant bollworm strains. (Indian farmers manage this by planting 'refuge crops' of non-Bt cotton.)
  • Effects on non-target insects (some debate).
  • Seed cost: Bt cotton seeds are more expensive than traditional seeds; farmers depend on seed companies.
  • Long-term ecosystem impact: still being studied.

✦ Answer: Bt cotton has a B. thuringiensis gene inserted; it produces a protein that kills caterpillar pests (especially bollworm). Advantages: less pesticide, higher yields. Concerns: pest resistance, seed cost, debated ecological effects.

Q12HARD· Disease

List four common diseases that affect cattle in India and their preventive measures.

▶ Show solution

Step 1 — Common cattle diseases.

(i) Foot-and-mouth disease (FMD):
  Viral; causes blisters in mouth and on feet, fever, lameness.
  Prevention: Annual vaccination, quarantine of infected animals, foot baths.

(ii) Anthrax:
  Bacterial; rapidly fatal. Sudden death with bleeding from natural orifices.
  Prevention: Annual vaccination, prompt isolation, careful disposal of carcasses (do NOT cut open).

(iii) Blackleg:
  Bacterial; clostridial; sudden lameness and death.
  Prevention: Vaccination (blackleg-anthrax combined vaccine), pasture rotation.

(iv) Brucellosis:
  Bacterial; causes abortion in pregnant cows and chronic milk production loss; also human disease.
  Prevention: Vaccination of heifers, removing infected animals.

(v) Mastitis (udder inflammation):
  Bacterial; causes painful, swollen udder and reduced milk yield/quality.
  Prevention: Hygienic milking, teat dipping after milking, treatment with antibiotics if infected.

Step 2 — Common prevention principles.
  • Annual vaccination as recommended by veterinary authority.
  • Quarantine new or sick animals.
  • Good hygiene (clean shed, clean drinking water).
  • Balanced feed and regular health checks.

✦ Answer: Four common diseases: foot-and-mouth disease, anthrax, blackleg, and brucellosis. Prevention: annual vaccination, isolation of sick animals, good hygiene, clean shelter and feed. Mastitis (udder inflammation) is also very common in dairy cattle.

Q13HARD· HOTS

Despite the success of the Green Revolution, why has India shifted focus toward 'sustainable' agriculture? Give four reasons.

▶ Show solution

Step 1 — Reason 1: Soil degradation.
  Decades of intensive chemical fertilisation have depleted soil organic carbon and micronutrients. Many Punjab and Haryana fields show salinity, alkalinity and reduced fertility.

Step 2 — Reason 2: Groundwater depletion.
  HYV rice and wheat are water-intensive. Tubewell irrigation has dropped groundwater tables by 1+ m/year in Punjab. By 2030, many districts could exhaust shallow aquifers.

Step 3 — Reason 3: Pesticide pollution.
  Heavy pesticide use has contaminated water (rivers, ponds), killed beneficial insects (bees, ladybugs), and shown links to human health issues (cancer, neurological disorders) in farming communities.

Step 4 — Reason 4: Climate change.
  Rising temperatures, erratic monsoons, increased extreme weather threaten the entire HYV-fertiliser-irrigation Green Revolution model. Climate-resilient crops + diverse cropping patterns are needed.

Step 5 — Reason 5 (bonus): Farmer income stagnation.
  Despite rising yields, smallholder farmer income has stagnated due to rising input costs (seed, fertiliser, pesticide). Sustainable, lower-input agriculture can be more profitable.

✦ Answer: Four key reasons: (i) soil degradation from over-fertilisation; (ii) groundwater depletion from water-intensive HYV crops; (iii) pesticide pollution affecting environment and health; (iv) climate change making current models unsustainable. The Evergreen Revolution aims to address all four.

Q14HARD· HOTS

A farmer has 1 hectare of land. He grows maize alone and gets 4000 kg yield. Another farmer with the same land grows maize + soybean intercropped — 3500 kg maize + 1200 kg soybean. Calculate which farmer earned more if maize sells at Rs. 15/kg and soybean at Rs. 40/kg.

▶ Show solution

Step 1 — Farmer 1 revenue.
  4000 kg × Rs. 15 = Rs. 60,000.

Step 2 — Farmer 2 revenue.
  Maize: 3500 × Rs. 15 = Rs. 52,500.
  Soybean: 1200 × Rs. 40 = Rs. 48,000.
  Total = Rs. 1,00,500.

Step 3 — Compare.
  Farmer 2 earned Rs. 1,00,500, which is Rs. 40,500 MORE than Farmer 1.

Step 4 — Why intercropping wins.
  Even though maize yield dropped a bit (3500 vs 4000), the soybean ADDS another high-value crop that wouldn't otherwise exist. The system uses sunlight, soil, water, and labour MORE efficiently. Additionally:
  • Soybean fixes nitrogen, improving soil for the next maize crop.
  • Risk is spread across two crops.

✦ Answer: Farmer 1 earned Rs. 60,000. Farmer 2 earned Rs. 1,00,500 — about 67 % more. Intercropping was clearly more profitable AND more sustainable.

Q15HARD· HOTS

Why does India encourage rooftop rainwater harvesting? Explain three direct benefits.

▶ Show solution

Step 1 — Benefit 1: Reduces groundwater extraction.
  Indian cities and farms rely heavily on groundwater. Tubewells are depleting aquifers faster than they recharge. Captured rainwater (instead of being lost to runoff) recharges these aquifers — slows the depletion.

Step 2 — Benefit 2: Provides clean drinking/irrigation water.
  Rooftop-collected rainwater (after first-flush diversion) is cleaner than groundwater in many areas. In cities, it reduces dependence on municipal water (which is often supplied at high energy cost from distant sources).

Step 3 — Benefit 3: Reduces urban flooding.
  In cities, paved surfaces send most rain to drains, causing flooding. Rainwater harvesting captures rain at source — less runoff, less drain overflow, less waterlogging.

Step 4 — Bonus: Cost-effective.
  A simple rooftop collection + ground recharge system costs ~ Rs. 30,000 for a typical home and can collect 1+ lakh litres in a monsoon. Pays back quickly in water-bill savings.

✦ Answer: (i) Recharges groundwater (reducing aquifer depletion). (ii) Provides clean water for drinking, irrigation, or household use. (iii) Reduces urban flooding by capturing rainfall at source. Bonus: economically viable for individual homes.

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The whole chapter, distilled. Read this the night before the exam.

•Crop improvement: higher yield, quality, biotic + abiotic resistance, wider adaptability, agronomic traits.
•Methods: hybridisation, GM, selection, mutation breeding.
•Cropping patterns: mixed, intercropping (row-wise), crop rotation (across seasons).
•Kharif (monsoon): rice, maize, cotton, soybean. Rabi (winter): wheat, gram, mustard.
•Manure: low % nutrients, slow release, improves soil structure. Fertilisers: high %, fast release, no soil structure benefit.
•Plant nutrients: 6 macro (N, P, K, Ca, Mg, S) + 7 micro (Fe, Cu, Zn, Mn, Mo, B, Cl).
•Irrigation: drip (most water-efficient) > sprinkler > furrow > flooding.
•Crop threats: weeds (Parthenium), insects (locust, stem borer), diseases (rust, blight).
•Storage losses controlled by silos, fumigation, cooling.
•Cattle: milch (Sahiwal, Murrah buffalo) vs draught (bullocks). Care includes shelter, feed, vaccinations.
•Poultry: layers (eggs) vs broilers (meat). Different breeds, different lifespans.
•Composite fish culture: 5-6 species at different ecological niches — maximises pond yield.
•Bee-keeping: honey + wax (direct) + pollination (much bigger indirect value). Italian bee for commercial use.
•Green Revolution (1960s-80s): HYV + fertiliser + irrigation. Made India food-secure.
•Evergreen Revolution (current): sustainable, lower-input, climate-resilient agriculture.

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Questions students ask

The real ones — pulled from the Q&A community and tutor sessions.

GM crops undergo extensive safety testing before commercial release. Bt cotton, the only major GM crop in India, has been safely cultivated for 15+ years. Most scientific consensus says approved GM crops are safe; controversy exists around ecological effects and corporate seed monopolies, not the direct food safety.

Indian land holdings have shrunk due to family inheritance partitioning over generations. Most Indian farms are < 2 hectares; American farms average 200+ acres. Smallholder farming has higher labour intensity per hectare but lower mechanisation — different economics.

Partially yes. Organic farming produces 20-40% less than HYV-fertiliser farming, but at high price premiums. About 0.6% of India's arable land is currently organic. Scaling to 100% is unrealistic — but mixed strategies (organic for niche markets, integrated nutrient management for staples) is the practical path.

Indian bee (Apis cerana indica): native, gentle, well-adapted to Indian climate but produces less honey (~5-7 kg/colony/year). Italian bee (Apis mellifera): introduced, higher honey yield (~ 30-50 kg/colony/year) but needs more management. Indian commercial apiculture uses Italian bees.

Monoculture exhausts specific soil nutrients, makes pest control harder (one pest = total crop loss), and harms biodiversity. Crop rotation, mixed cropping, and intercropping address these problems while still allowing high yields.

Watershed management involves treating water as a community resource at the catchment level: check dams to slow runoff, contour ploughing to reduce erosion, recharge structures for groundwater. Result: more water available for irrigation, less flooding, and sustainable productivity over decades.

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Improvement in Food Resources

By the end of this chapter you'll be able to…

Before you start — revise these

Improvement in Food Resources — Class 9 (CBSE)

1. The story — Green Revolution to Sustainable Agriculture

2. Crop variety improvement

Methods to improve a crop variety

Examples of HYV varieties

3. Cropping patterns — getting more from the same land

(a) Mixed cropping

(b) Intercropping

(c) Crop rotation

(d) Seasonal cropping in India

4. Nutrient management — manure vs fertilisers

Manure

Fertilisers

Why combine both?

5. Irrigation — water management

Sources of irrigation

Modern irrigation techniques

Watershed management

6. Crop protection — pests and weeds

Weeds

Insect pests

Diseases

Storage losses

7. Animal husbandry — cattle, poultry, fish

Cattle farming

Poultry farming

Fish farming (aquaculture)

Bee keeping (apiculture)

8. Sustainable agriculture — the future

9. Closing thought

Key formulas & results

Common mistakes & fixes

NCERT exercises (with solutions)

Practice problems

5-minute revision

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Is genetic modification of crops safe?

Why are Indian farms smaller than American farms?

Is organic farming feasible at scale for India?

What's the difference between Indian and Italian bees for apiculture?

Why is monoculture (single-crop farming) discouraged?

How does watershed management increase agricultural productivity?

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Matter in Our Surroundings

Is Matter Around Us Pure?

Atoms and Molecules

Structure of the Atom

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