What is Water Quality, Conservation & Exercises in Class 12 Geography NCERT?

Interactive NCERT Class 12 Geography lesson on Water Quality, Conservation & Exercises

What are the main causes of water pollution in India?

Major causes of water pollution in India are untreated municipal sewage, industrial effluents (heavy metals, chemicals), agricultural run-off (fertilisers, pesticides), discharge from religious and cultural activities, oil spills, and the dumping of solid waste into rivers and lakes.

What is rainwater harvesting?

Rainwater harvesting is the technique of collecting and storing rainwater for later use. It involves capturing runoff from rooftops or open ground in tanks, recharging wells and groundwater, or directing runoff into ponds and percolation pits.

What is the National Water Policy?

The National Water Policy of India sets out priorities for water use: drinking water comes first, followed by irrigation, hydro-power, navigation, industrial and other uses. The policy emphasises conservation, equitable distribution, and treating water as a finite resource and an economic good.

What is the difference between water pollution and water scarcity?

Water scarcity refers to a shortage of usable water relative to demand, usually because of low rainfall, over-exploitation, or rising population. Water pollution refers to contamination that makes available water unfit for use, even when its quantity is adequate.

How can we conserve water at home?

Households can conserve water by fixing leaking taps, using low-flow fixtures, harvesting rainwater on rooftops, recycling water for gardens, taking shorter showers, running washing machines and dishwashers only with full loads, and treating greywater for reuse.

TOPIC 12 OF 27

Water Quality, Conservation & Exercises

🎓 Class 12 Social Science CBSE Theory Chapter 4 — Water Resources ⏱ ~28 min

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Water Quality, Conservation & NCERT Exercises

NCERT India: People and Economy — Unit III, Chapter 4 (Part 3)

From Quantity to Quality: India's Other Water Crisis

So far we have looked at how much water India has and where it goes. But there is a second crisis quietly running alongside the quantity crisis: the quality of the water that remains. Available water resources are degrading rapidly. India's rivers carry chemical and biological pollution, her groundwater is contaminated with arsenic, fluoride and nitrates in places, and her urban tanks have shrunk under the weight of construction. This part of the chapter examines water-quality issues, the conservation and management measures that can rescue the situation, and closes with a complete walk-through of the NCERT end-of-chapter exercises.

Definition

Water quality^? refers to the purity of water — water that is free of unwanted foreign substances. It is impaired when micro-organisms, chemicals, industrial waste, agricultural runoff or domestic effluents enter and dissolve in or remain suspended in water bodies.

4.3 Deterioration of Water Quality

The per-capita availability of water is dwindling because of population growth. At the same time, the available resources are being polluted with industrial, agricultural and domestic effluents, further limiting usable supplies. When toxic substances enter lakes, streams, rivers and oceans, they get dissolved or lie suspended in water. The result is pollution — water quality deteriorates and aquatic ecosystems are damaged. Sometimes these pollutants seep down and pollute the groundwater as well.

Sources of Water Pollution

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Industrial Effluents

Untreated effluents from tanneries, paper mills, textile units, sugar mills, distilleries, chemical and metal industries carry heavy metals, dyes and toxic compounds straight into rivers.

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Agricultural Runoff

Fertilisers, pesticides and insecticides washed off fields by rain enter rivers and percolate into groundwater — raising nitrate and pesticide levels.

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Domestic Sewage

Solid and liquid urban sewage — often only partly treated — flows into the nearest drain, then river, carrying pathogens and organic load.

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Religious Offerings

Flowers, oil, plastic offerings, ash and idols immersed in rivers add to organic load and obstruct natural flow, especially in pilgrim cities.

The major rivers of the country generally retain better water quality in the less densely populated upper stretches in hilly areas. In the plains, river water is used intensively for irrigation, drinking, domestic and industrial purposes. Drains carrying agricultural fertilisers and insecticides, domestic solid and liquid wastes, and industrial effluents all join the rivers. The concentration of pollutants is especially high during the summer season when river flow is low.

India's Most Polluted Rivers

The Central Pollution Control Board (CPCB), in collaboration with State Pollution Control Boards, monitors water quality at 507 stations across India. The data show that organic and bacterial contamination continues to be the main pollution problem. The Yamuna is the most polluted river in the country between Delhi and Etawah. Other severely polluted stretches include the Sabarmati at Ahmedabad, the Gomti at Lucknow, the Kali, the Adyar, the Cooum (entire stretches), the Vaigai at Madurai, the Musi of Hyderabad and the Ganga at Kanpur and Varanasi.

Fig 4.9 — Some of India's Most Polluted River Stretches

The Yamuna between Delhi and Etawah ranks as India's most polluted river stretch, but several others — Cooum, Sabarmati, Musi, Ganga at Kanpur — are also heavily impacted.

Groundwater Pollution

Groundwater pollution has occurred due to high concentrations of heavy metals, fluoride and nitrates in different parts of the country. In particular:

Arsenic — affects parts of West Bengal and Bihar, where over-extraction has drawn arsenic-bearing layers into the active aquifer.
Fluoride — affects parts of Rajasthan and Maharashtra, where deep aquifers naturally carry fluoride; over-pumping concentrates it further.
Nitrates — from fertilisers, especially in heavily-irrigated agricultural belts.

Health Impact

Long-term exposure to arsenic causes skin lesions and cancers; excess fluoride causes fluorosis with crippling skeletal damage; high nitrates in drinking water are linked to "blue baby" syndrome in infants. Water quality is therefore a public-health issue, not only an environmental one.

Legislative Response

India has put in place a series of laws to control water pollution — most notably the Water (Prevention and Control of Pollution) Act, 1974, the Water Cess Act, 1977, and the Environment Protection Act, 1986. However, implementation has been weak. As of 1997, 251 polluting industries were located along rivers and lakes; the Cess Act has had only marginal impact. There is a strong need to generate public awareness about the importance of water and the impact of pollution. Public action can be very effective in reducing pollutants from agricultural, domestic and industrial sources.

SOURCE — Towns on the Ganga

L3 Apply

Refer to NCERT Fig 4.2 (The Ganga and its Tributaries and Towns Located on Them). Find out:

Which are the major towns/cities located on the bank of the Ganga and its tributaries?
Which industries are concentrated in these cities?
How do these cities and industries contribute to the pollution of the Ganga?

Guidance

Major Ganga-bank cities include Haridwar, Kanpur (leather/tanneries), Allahabad/Prayagraj, Varanasi, Patna and Kolkata. The Yamuna passes Delhi (electroplating, sewage), Mathura (refineries) and Agra. These industrial centres contribute heavy-metal, organic and pathogen loads to the Ganga, which is why the Kanpur and Varanasi stretches are among India's most polluted.

Water Conservation and Management

Given the declining availability of freshwater and the rising demand, the need has arisen to conserve and effectively manage this precious life-giving resource for sustainable development. Sea/ocean water is largely ineffective for human use because of the high cost of desalination. India therefore has to take quick steps and make effective policies and laws, and adopt practical measures for conservation. Besides developing water-saving technologies and methods, attempts must also be made to prevent pollution. There is an urgent need to encourage watershed development, rainwater harvesting, water recycling and reuse, and conjunctive use of water for sustaining supply over the long run.

Recycling and Reuse of Water

One way to expand fresh-water availability is by recycling and reusing. Reclaimed wastewater of lesser quality can be used by industries for cooling and fire-fighting — reducing water cost. In urban areas, water from bathing or washing utensils can be used for gardening. Water used to wash vehicles can also be redirected to gardening. This conserves better-quality water for drinking. Currently, recycling is practised on a limited scale, but there is enormous scope for replenishing supplies through it.

Watershed Management

Watershed management^? refers to the efficient management and conservation of surface and groundwater resources within a defined drainage basin. It involves the prevention of runoff and the storage and recharge of groundwater through methods like percolation tanks, recharge wells, contour bunds, check-dams and afforestation. In a broader sense, watershed management includes the conservation, regeneration and judicious use of all natural resources — land, water, plants and animals — together with people. It seeks to bring about balance between natural resources and society, and its success depends critically on community participation.

The Central and State Governments have launched many watershed development programmes, some of which are also being implemented by NGOs. Haryali is a centrally-sponsored watershed development project that aims at enabling rural populations to conserve water for drinking, irrigation, fisheries and afforestation, executed through Gram Panchayats with people's participation. Neeru-Meeru ("Water and You") in Andhra Pradesh and the Arvari Pani Sansad in Alwar, Rajasthan, have built percolation tanks, dug-out ponds (johads) and check-dams through community effort. Tamil Nadu has made rainwater-harvesting structures compulsory in all new buildings.

Fig 4.10 — A Watershed in Action

A watershed approach catches every drop — afforestation on the ridge, terracing on slopes, check-dams in streams, percolation tanks, and recharge wells in the village.

Case Study: Ralegan Siddhi, Maharashtra

NCERT Box: Watershed Development at Ralegan Siddhi, Ahmadnagar

Ralegan Siddhi is a small village in Ahmadnagar district that has become a national example of watershed-led transformation. In 1975 the village was caught in poverty and illicit liquor trade. The transformation began when a retired army personnel — Anna Hazare — settled there and led a programme of family planning, voluntary labour, prevention of open grazing, tree-felling and liquor.

Work began with the repair of a percolation tank whose embankment had leaked. People rebuilt the bund themselves; for the first time in living memory, the seven wells below it filled with water in summer. A youth group called Tarun Mandal was formed; dowry, caste discrimination and untouchability were banned; open grazing was replaced with stall-feeding; water-intensive crops like sugarcane were prohibited in favour of low-water pulses, oilseeds and selected cash crops. A school was built using only village resources. Local elections were held by consensus. Nyay Panchayats (informal courts) replaced police cases.

Today Ralegan Siddhi has adequate water; agriculture is flourishing — though fertiliser and pesticide use is high. The challenge now is sustaining the gains across generations.

— NCERT, India: People and Economy

Other model watershed cases include Hiware Bazar in Maharashtra (close to Ralegan Siddhi) and Sukhomajri in Haryana — pioneer of the participatory watershed approach in the 1970s. In these villages, integrated treatment of land and water has revived agriculture and reversed migration.

DISCUSS — Lessons from Ralegan Siddhi

L5 Evaluate

Ralegan Siddhi turned around through community labour, voluntary effort and prohibition of water-intensive crops. Discuss in groups:

Could the Ralegan model work in your own village or town? What conditions would make it succeed or fail?
What role should government schemes (like PMKSY, Atal Bhujal) play, and where should the community lead?

Guidance

The Ralegan model needs strong local leadership, broad social consensus and willingness to change cropping patterns. It works best when the community itself owns the project and the State acts as a supportive partner — providing technical help, financing recharge wells and check-dams, and certifying outcomes — rather than dictating from above. Without these conditions, top-down watershed schemes typically fail in the implementation phase.

Rainwater Harvesting

Rainwater harvesting^? is a method of capturing and storing rainwater for various uses. It is also used to recharge groundwater aquifers. It is a low-cost and eco-friendly technique that preserves every drop of water by guiding rain into borewells, pits and wells. Rainwater harvesting increases water availability, checks the declining groundwater table, improves the quality of groundwater through dilution of contaminants like fluoride and nitrates, prevents soil erosion and flooding, and arrests salt-water intrusion in coastal areas if used to recharge aquifers.

Traditional Rainwater Harvesting in India

Indians have practised rainwater harvesting for centuries through diverse local techniques. In rural areas it is done using surface storage bodies like lakes, ponds and irrigation tanks. Some celebrated traditional structures:

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Tanka / Kund (Rajasthan)

A covered underground tank built near or inside the house or village to store harvested rainwater — the lifeline of arid Rajasthan's desert villages.

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Johad (Rajasthan)

A small earthen check-dam across a seasonal stream that captures monsoon water for cattle and groundwater recharge. Revived widely in Alwar district.

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Ahar-Pyne (Bihar)

South Bihar's ancient system: ahar = catchment basin, pyne = artificial channel. Water flows from upland through pynes into ahars for paddy irrigation.

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Kuls (Himachal)

Long irrigation channels carved along hillsides that take glacier melt-water from high-altitude streams to terraced fields below.

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Eri (Tamil Nadu)

A chain of tanks linked through canals: surplus water from each tank flows down to the next, watering the paddy fields of the lower delta.

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Virda (Kachchh)

Shallow wells dug in low-lying salt depressions (rann) by Maldhari pastoralists to skim off the freshwater that floats above the saline layer.

Fig 4.11 — Traditional Rainwater Harvesting Cross-Sections

Tankas, johads, rooftop systems and chain-tanks (eris) all serve the same goal — capture every drop of monsoon water before it returns to the sea.

Modern Rooftop Rainwater Harvesting

There is wide scope to use rainwater-harvesting technique to conserve precious water. It can be done by harvesting rainwater on rooftops and open spaces. Harvesting rainwater also decreases the community's dependence on groundwater for domestic use. Besides bridging the demand-supply gap, it can save the energy used to pump groundwater, since recharge raises the water-table. Rainwater harvesting is being taken up on a massive scale in many states. Urban areas can specially benefit, as water demand has already outstripped supply in most cities and towns. Apart from these, the issues of desalination of brackish water in arid and semi-arid areas, inter-linking of rivers from surplus to deficit basins, and the pricing of water are also important — though contested — remedies for India's water problem.

National Water Policy and Schemes

Successive governments have framed National Water Policies in 1987, 2002 and 2012 to provide a national framework for assessing the situation and making recommendations for conservation, development and management of water resources.

Highlights of National Water Policy 2012

National Water Policy, 2012

Need for a National Water Framework Law — a comprehensive legislation for optimum development of inter-State rivers and river valleys.
After meeting basic needs (safe drinking water, sanitation, food security, livelihood support, eco-system needs), water should be treated as an economic good to promote conservation and efficient use.
Adaptation strategies for climate change in design and management of water-resource structures.
Develop water footprints and water auditing for benchmarking different uses.
Remove disparity in water-supply standards between urban and rural areas.
Manage water-resources projects with community participation.

National Water Mission

The National Water Mission, announced under the National Action Plan on Climate Change, aims to ensure integrated water-resource development with greater equity, distribution, conservation and efficient use — with a target of improving water-use efficiency by 20 per cent.

Atal Bhujal Yojana (Atal Jal), 2019

Atal Bhujal Yojana — launched in 2019 — is being implemented in 8,220 water-stressed Gram Panchayats across 229 administrative blocks/talukas in 80 districts of seven states: Gujarat, Haryana, Karnataka, Madhya Pradesh, Maharashtra, Rajasthan and Uttar Pradesh. These states account for about 37 per cent of all over-exploited, critical and semi-critical groundwater blocks in India. The key idea is to bring about a behavioural change in the community — from consumption to conservation and smart water management.

Jal Kranti Abhiyan (2015–16)

The Jal Kranti Abhiyan, launched in 2015–16, aims to ensure water security through per-capita availability. Its components include: identifying one water-stressed village in each of 672 districts as a "Jal Gram"; developing model command areas of about 1,000 hectares in each region; abatement of pollution; construction of arsenic-free wells in selected areas; and creating mass awareness through schools, social media and the press.

LET'S EXPLORE — Recycling at Home

L3 Apply

Observe the quantity of water used at your home in various activities and list the ways in which the water can be reused or recycled.

Guidance

Some easy household reuse ideas: collect water from vegetable washing for the kitchen garden; use water from RO purifier rejection for floor mopping or toilets; redirect water used for washing vehicles to potted plants; reuse final-rinse laundry water for cleaning the bathroom; install a dual-flush WC and a low-flow shower head; and explore a small rooftop rainwater harvesting tank to recharge a household borewell.

Conclusion: From Crisis to Conservation

Water has moved, in a single generation, from being seen as an inexhaustible gift of the monsoon to being recognised as a scarce resource that must be assessed, conserved and shared with care. India sits on only 4 per cent of the world's water but supports more than 17 per cent of its people; her per-capita availability has slipped from 5,177 m³ to roughly 1,341 m³; her rivers carry growing pollution and her groundwater is being depleted in heartland states. The way forward lies less in giant dams and more in watershed-led, community-driven, decentralised conservation — combined with cleaner industries, better-priced water and a culture of reuse. Ralegan Siddhi shows what is possible at one end of the spectrum, and the National Water Policy lays down the principles at the other. The choices made in the next two decades will determine whether India keeps her water within the stress zone or slips into permanent scarcity.

NCERT Exercises — with Model Answers

Q1. Choose the right answer from the options given.

(i) Which one of the following types describes water as a resource?

(a) Abiotic resource
(b) Non-renewable resource
(c) Biotic resource
(d) Non-cyclic resource

(ii) Which one of the following south Indian states has the highest groundwater utilisation (in per cent) of its total ground water potential?

(a) Tamil Nadu
(b) Karnataka
(c) Andhra Pradesh
(d) Kerala

(iii) The highest proportion of the total water used in the country is in which one of the following sectors?

(a) Irrigation
(b) Industries
(c) Domestic use
(d) None of the above

Q2. Answer the following questions in about 30 words.

(i) It is said that the water resources in India have been depleting very fast. Discuss the factors responsible for depletion of water resources.

(ii) What factors are responsible for the highest groundwater development in the states of Punjab, Haryana, and Tamil Nadu?

(iii) Why the share of agricultural sector in total water used in the country is expected to decline?

(iv) What can be possible impacts of consumption of contaminated/unclean water on the people?

Q3. Answer the following questions in about 150 words.

(i) Discuss the availability of water resources in the country and factors that determine its spatial distribution.

(ii) The depleting water resources may lead to social conflicts and disputes. Elaborate it with suitable examples.

(iii) What is watershed management? Do you think it can play an important role in sustainable development?

Project Work

Discuss the issues highlighted in the news items about water pollution, intensive irrigation in Punjab/Haryana/W. UP, and recycle/reuse of water at home.

Map Work

On an outline map of India, mark and label the following:

The river basins of the Ganga, Brahmaputra, Indus, Mahanadi, Godavari, Krishna, Kaveri, Narmada, Tapi.
States with high groundwater utilisation: Punjab, Haryana, Rajasthan, Tamil Nadu.
Multi-purpose projects: Bhakra-Nangal (Sutlej), Damodar Valley (Damodar), Hirakud (Mahanadi), Nagarjuna Sagar (Krishna), Tungabhadra (Tungabhadra), Sardar Sarovar (Narmada).
Most polluted river stretches: Yamuna (Delhi–Etawah), Ganga at Kanpur and Varanasi, Sabarmati at Ahmedabad, Cooum, Musi at Hyderabad.
Lagoon coasts: Kerala, Odisha, West Bengal.

✍ Assertion-Reason Questions

Assertion (A): The Yamuna is the most polluted river in India between Delhi and Etawah.
Reason (R): The Yamuna receives most of Delhi's untreated domestic sewage and industrial effluents along this stretch, with very low river flow during summers.

(A) Both A and R are true, and R is the correct explanation of A

(B) Both A and R are true, but R is not the correct explanation of A

(D) A is false but R is true

Assertion (A): Tamil Nadu has made rainwater-harvesting structures compulsory in all new buildings.
Reason (R): Tamil Nadu is a water-surplus state and has no need to conserve groundwater.

(A) Both A and R are true, and R is the correct explanation of A

(B) Both A and R are true, but R is not the correct explanation of A

(D) A is false but R is true

Assertion (A): The Atal Bhujal Yojana (Atal Jal) was launched to bring about behavioural change in water-stressed Gram Panchayats.
Reason (R): Atal Bhujal targets 8,220 Gram Panchayats in 80 districts of seven states that together account for about 37% of India's over-exploited or critical groundwater blocks.

(A) Both A and R are true, and R is the correct explanation of A

(B) Both A and R are true, but R is not the correct explanation of A

(D) A is false but R is true

📖 Chapter Summary — Key Takeaways

Water is a cyclic, renewable but limited resource. 71% of Earth is water; just 3% is fresh; only a small fraction is effectively usable.
India holds 4% of the world's water but supports 17%+ of its population on 2.45% of the world's area.
Total annual precipitation in India is ~4,000 cu km; total surface + replenishable groundwater is 1,869 cu km; total utilisable water is ~1,122 cu km.
Surface water: 10,360 rivers; mean flow 1,869 cu km; only 690 cu km (32%) usable. The Ganga, Brahmaputra and Barak carry 60% of surface water.
Replenishable groundwater is 432 cu km; over-exploited in Punjab, Haryana, Rajasthan, Tamil Nadu.
Sectoral use: Irrigation 89% · Domestic 6% · Industry 5% of surface water (groundwater split 92/3/5).
Per-capita availability: 5,177 m³ (1951) → 1,341 m³ (2025) → 1,140 m³ (2050). Below 1,700 = stress; below 1,000 = scarcity.
Irrigation types: canal, tank, dug-well, tube-well. Tube-wells dominate Punjab/Haryana/W.UP/TN.
Multi-purpose projects: Bhakra-Nangal, DVC, Hirakud, Nagarjuna Sagar, Tungabhadra, Sardar Sarovar — Nehru's "temples of modern India".
Narmada Bachao Andolan (Medha Patkar) raised the costs of large dams — displacement, environmental damage.
Polluted rivers: Yamuna (Delhi-Etawah, most polluted), Sabarmati, Cooum, Musi, Ganga at Kanpur/Varanasi. Groundwater pollution: arsenic (WB, Bihar), fluoride (RJ, MH).
Conservation: watershed management (Ralegan Siddhi, Anna Hazare; Hiware Bazar; Sukhomajri), rainwater harvesting (tanka, johad, kund, eri, kuls, ahar-pyne, virda), recycle/reuse, rooftop RWH.
Policy: National Water Policy (1987, 2002, 2012), National Water Mission, Atal Bhujal Yojana 2019, PMKSY, Jal Kranti Abhiyan.

📚 Glossary — Key Terms

Cyclic ResourceA resource whose total quantity is fixed but circulates through different states — water is the classic example.

Utilisable WaterThe portion of total water that can actually be put to beneficial use; in India, ~1,122 cu km out of 1,869 cu km.

Surface WaterWater in rivers, lakes, ponds, reservoirs and tanks — visible above the ground.

GroundwaterWater held in saturated soil and rock layers (aquifers) below the surface.

Per-Capita AvailabilityRenewable water available per person per year. Below 1,700 m³ = stress; below 1,000 m³ = scarcity.

Multi-Purpose ProjectA river-valley scheme that delivers irrigation, hydro-power, flood control, drinking water, navigation and fisheries together.

Bhakra-NangalMajor project on the Sutlej feeding canals across Punjab, Haryana, Rajasthan, Himachal Pradesh.

Damodar Valley CorporationIndia's first multi-purpose river project (1948), modelled on the Tennessee Valley Authority.

HirakudOne of the world's longest earthen dams, on the Mahanadi in Odisha.

Sardar SarovarMassive dam on the Narmada; centre of the Narmada Bachao Andolan led by Medha Patkar.

Watershed ManagementConservation and judicious use of land, water and biota within a drainage basin — pioneered at Ralegan Siddhi and Sukhomajri.

Rainwater HarvestingCapturing rainwater for use or to recharge aquifers — rooftops, tankas, kunds, johads.

Tanka / KundCovered underground water tanks of Rajasthan that store rooftop or surface rainwater for drinking.

JohadSmall earthen check-dams of Rajasthan that capture runoff for cattle and groundwater recharge.

Atal Bhujal Yojana2019 scheme for 8,220 water-stressed Gram Panchayats in 80 districts of seven states.

National Water PolicyFramework laid down by the Centre in 1987, 2002 and 2012 for water assessment, allocation and conservation.

PMKSYPradhan Mantri Krishi Sinchayee Yojana — "Har Khet Ko Pani" and "Per Drop More Crop" (2015–16).

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