Class 9 Science NCERT Solutions Chapter 13: Earth as a System — Energy, Matter, and Life | Boundless Maths
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Chapter 13: Earth as a System
Energy, Matter, and Life

Complete NCERT Solutions for Chapter 13 of the new Class 9 Science Exploration textbook (CBSE 2026-27) — every Think It Over, Activity, Pause & Ponder, Revise Reflect Refine, and Journey Beyond question on this one page, with full reasoning for the geosphere, hydrosphere, cryosphere, atmosphere, biosphere, and the biogeochemical cycles that connect them.

As the final chapter of the Class 9 Science 'Exploration' textbook, this chapter ties together ideas from earlier chapters — energy, cycles, and ecosystems — into a single connected view of how Earth's four spheres interact. Expect exam questions on the carbon cycle, the greenhouse effect and climate change, and how a disruption in one sphere, like excess CO2 in the atmosphere, ripples outward to affect the oceans, ice sheets, and living things — themes that make this chapter as much about environmental awareness as classical earth science.

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Overview

What Chapter 13 Is Really About

Earth as a System: Energy, Matter, and Life is the closing chapter of Class 9 Science — it brings together ideas from across the whole book (energy, cycles, motion of air and water) into one connected picture of the Earth as five interacting spheres: geosphere, hydrosphere, cryosphere, atmosphere, and biosphere. It builds from uneven heating and insolation, through local and planetary winds and ocean currents, to the water, carbon, nitrogen, and oxygen cycles that keep nutrients moving between living and non-living systems, and finally to how human activity is disturbing this delicate balance. Every question is solved here, section by section, exactly as the textbook presents them.

🌍

Earth's Five Spheres

Geosphere, hydrosphere, cryosphere, atmosphere and biosphere — and how a disturbance in one ripples through all the others.

☀️

Uneven Heating, Winds & Currents

Insolation, albedo, atmospheric layers, local breezes, planetary wind belts, and ocean gyres like the Gulf Stream.

♻️

Biogeochemical Cycles & Human Impact

Water, carbon, nitrogen and oxygen cycles, and how fossil fuels, deforestation and fertiliser overuse disturb this balance.

Section A

Think It Over (Chapter Opener)

4 Questions
Q1How does the warming of Arabian Sea water affect the southwest monsoon in India?

Answer: warmer Arabian Sea water increases evaporation, adding more moisture to the air above it, which affects the southwest monsoon in two main ways:

  • More moisture feeds the monsoon: the extra water vapour is carried by the southwest monsoon winds blowing towards India, which can intensify overall rainfall.
  • Greater variability and unpredictability: instead of steady, evenly-distributed rainfall, this leads to sudden, heavy bursts of rain in some regions (causing floods) and longer dry spells in others (causing drought).
Q2If a large forest is cleared, how can that affect the flow of a river in that area?

Answer: tree roots normally hold soil together, absorb rainwater, and release it slowly into streams through gradual infiltration and transpiration. Clearing a forest disrupts this in several ways:

  • More sudden flooding after rain: with fewer roots to absorb rainwater, more of it runs off the surface quickly instead of soaking in, causing the river to rise suddenly and flood.
  • Less water in the dry season: groundwater recharge falls, so the river may carry much less water once the rains stop.
  • Increased soil erosion: without roots to hold the soil, erosion increases, and the silt washed into the river can raise the riverbed — increasing the risk of future flooding.
Q3What might happen to coastal cities in India if glaciers and polar ice keep melting faster?

Answer: the extra meltwater from glaciers and polar ice flows into the oceans and raises the global sea level. Coastal cities such as Mumbai, Chennai and Kolkata could face:

  • More frequent flooding and submergence of low-lying areas.
  • Saltwater intrusion into groundwater and farmland.
  • Greater damage from storm surges.
  • Over the long term, some low-lying coastal areas could become permanently submerged, forcing people to relocate.
Q4How would increasing carbon dioxide levels in the atmosphere affect the ocean plankton?

Answer: oceans absorb a large share of atmospheric CO₂, and this affects ocean plankton in a clear chain of steps:

  • Dissolved CO₂ forms carbonic acid, making seawater more acidic — a process called ocean acidification.
  • Many plankton species build shells or skeletons from calcium carbonate; in more acidic water these shells dissolve more easily or are harder to form, weakening or killing these organisms.
  • Since plankton forms the base of the marine food chain, their decline would disrupt fish populations and the wider marine ecosystem that depends on them.
Section B

Activities 13.1 – 13.2

2 Activities
13.1Let us explore (Interacting Spheres, Fig. 13.1) — identify the spheres, and explain how a disturbance in one leads to changes in others.
1. Identifying the spheres in Fig. 13.1

Geosphere — the rocky mountain slopes and soil; Hydrosphere — the lake; Cryosphere — the snow-covered mountain peaks; Atmosphere — the surrounding air/sky above the scene; Biosphere — the grazing sheep, the shepherd and the grass, i.e. the living organisms in the scene.

2. How does snow become part of the lake?

As temperatures rise (for example, in warmer months), the snow on the mountain slopes melts. This meltwater flows downhill as small streams and runoff, eventually reaching and adding to the water of the lake below, thereby moving matter from the cryosphere into the hydrosphere.

3. Effect of less snowfall on the lake and grass

Less snow accumulation in winter means less meltwater will feed the lake in the following months, so the lake's water level would drop. With less water available, the grass growing around the lake would receive less moisture and could dry up or grow poorly, reducing the grass available for the sheep to graze on and affecting the shepherd's livelihood.

4. How the spheres are interconnected

A change in any one sphere ripples through the others because they constantly exchange matter and energy. For example:

  • Less snowfall in winters (cryosphere) → less water reaches the lake in summer (hydrosphere) → less water is available to support the growth of grass (biosphere).
  • Warmer Arabian Sea water (hydrosphere) → more evaporation → fluctuations in the southwest monsoon (atmosphere) → floods in some regions of India and drought in others (disrupting the hydrosphere).
  • Rising atmospheric temperature → faster melting of glaciers and polar ice (cryosphere) → flooding of low-lying regions and, over time, rising sea levels that threaten coastal cities → habitat loss within ecosystems (biosphere).
Conclusion

The Earth's spheres do not act in isolation — they form one interconnected system in delicate balance.

13.2Let us find out — complete Table 13.1 with the albedo of common surfaces, and explain what the pattern shows.

Typical albedo values (these can vary somewhat depending on the exact surface condition, sun angle, and the source used):

S. No.MaterialAlbedo
1.Snow0.80 – 0.90 (given)
2.Ice0.50 – 0.70 (given)
3.Crushed rock0.25 – 0.30 (given)
4.Light coloured soil0.25 – 0.45
5.Black soil0.05 – 0.15
6.Ocean water0.06 – 0.10 (higher near sunrise/sunset, when the Sun's angle is low)

Inference: snow and ice have the highest albedo, so they reflect most incoming solar radiation and stay cold — this keeps polar regions cold and creates the ice–albedo feedback (as ice melts, the darker surface beneath absorbs more heat, causing further melting). Black soil and ocean water have low albedo, absorb more radiation, and are relatively warmer, while light coloured soil lies in between.

Section C

Pause and Ponder

6 Questions
P1Visit the PhET greenhouse-effect simulation and study the effect of the concentration of greenhouse gas on surface temperature.

Answer: on the simulation (phet.colorado.edu/en/simulations/greenhouse-effect), increasing the concentration of a greenhouse gas (such as CO₂) increases the amount of outgoing infrared radiation that gets trapped in the atmosphere instead of escaping to space. As a result, the simulated surface temperature rises as greenhouse gas concentration increases, confirming that greenhouse gases warm the Earth by trapping re-radiated heat — and that more of these gases means more warming.

P2How does the cool mountain breeze benefit agriculture activity, particularly the crops and soil?

Answer: the mountain breeze is cool and dense air flowing down from the slopes into the valley after sunset. This lowers night-time temperatures in the valley, which can help form dew that adds moisture to crops and soil, moderates extreme daytime heat stress on plants, and helps disperse stagnant warm air pockets. This cooler, moving air reduces excessive evaporation of soil moisture and supports better temperature conditions for crop growth and healthier soil in mountainous farming regions like Himachal Pradesh or Uttarakhand.

P3What happens to the warm surface water from the equator as it travels toward the poles? What impact does this movement have on the area?

Answer: warm equatorial surface water is carried poleward by ocean currents such as the Gulf Stream and its extension, the North Atlantic Drift. As this water moves towards higher latitudes, it gradually loses heat to the atmosphere and cools.

Impact: the heat it releases warms the nearby coastal regions, moderating their climate — for example, the North Atlantic Drift keeps many European ports ice-free even in winter, despite their high latitude. This moderating effect also supports trade, commerce and coastal ecosystems. After releasing its heat, the now-cooler, denser water sinks and slowly returns towards the equator through deeper ocean currents, completing the circulation.

P4The CO₂ dissolved in the ocean is disturbed when the global temperature increases. What will happen to marine life?

Answer: warmer water holds less dissolved gas, so as ocean temperature rises, the ocean's capacity to absorb and hold CO₂ decreases. This leaves more CO₂ in the atmosphere, intensifying global warming further (a positive feedback loop).

At the same time, the CO₂ already dissolved makes seawater more acidic, which harms calcifying marine organisms such as corals, shellfish and some plankton — weakening their shells and skeletons, causing coral bleaching, and disrupting the base of marine food chains. Warmer, more acidic and lower-oxygen water can also force fish and other species to migrate to cooler areas, disrupting fisheries and local ecosystems.

P5What would happen to plants and animals on Earth if the biogeochemical cycles were disrupted and stopped? Explain by giving a few examples.

If the biogeochemical cycles stopped, essential nutrients would no longer be recycled between the living and non-living components of the Earth, and life would not be sustainable:

  • Water cycle: no evaporation–condensation–precipitation cycle would mean no fresh rainfall reaching rivers, lakes and groundwater — plants, animals and humans would lose access to fresh water.
  • Carbon cycle: if CO₂ were not returned to the atmosphere (through respiration, decomposition, and combustion) and re-absorbed (through photosynthesis), plants would eventually run out of CO₂ for photosynthesis, stopping food and oxygen production for almost all life.
  • Nitrogen cycle: if atmospheric nitrogen were never fixed into usable compounds (ammonia, nitrates), plants could not build proteins and nucleic acids, so they could not grow — and animals that depend on plants (directly or indirectly) for nitrogen would also be unable to survive.
  • Oxygen cycle: if the balance between oxygen-releasing photosynthesis and oxygen-consuming respiration/combustion broke down, atmospheric oxygen levels needed for aerobic life could no longer be maintained.

In short, biogeochemical cycles keep essential nutrients available to living organisms — without them, ecosystems would collapse and life as we know it could not continue.

P6Discuss how human activities increase the concentration of greenhouse gases in the atmosphere. What would you do as an individual to reduce the emission of greenhouse gas?

How human activities increase greenhouse gases:

  • Burning fossil fuels (coal, oil, gas) for electricity, transport and industry releases large amounts of CO₂.
  • Deforestation reduces the number of trees that absorb CO₂, and burning or decomposing cleared trees releases the carbon they had stored.
  • Livestock rearing and paddy cultivation release methane (CH₄), a potent greenhouse gas.
  • Overuse of nitrogenous fertilisers releases nitrous oxide, another greenhouse gas, and also causes eutrophication of water bodies.
  • Certain industrial processes and old refrigerants release other greenhouse gases and ozone-depleting substances.

What an individual can do (open-ended — students should reflect on their own routine; some examples):

  • Use public transport, cycle or walk instead of private vehicles where possible; carpool when driving is necessary.
  • Save electricity by switching off unused appliances/lights and using energy-efficient devices.
  • Plant trees and support afforestation drives.
  • Reduce, reuse and recycle materials to cut down on the energy used in manufacturing new products.
  • Reduce food waste and avoid overuse of fertilisers in home gardens/farms; adopt simple, mindful, eco-friendly habits as encouraged by initiatives like Mission LiFE.
Section D

Revise, Reflect, Refine

15 Questions
Q1Choose the most appropriate option to describe the role of biogeochemical cycles in an ecosystem.

(i) To provide food directly to all organisms. (ii) To recycle essential nutrients between biotic and abiotic components. (iii) To create new elements for use by living things. (iv) To remove pollutants and toxins from the organism.

Answer: (ii) To recycle essential nutrients between biotic and abiotic components. Biogeochemical cycles (water, carbon, nitrogen, oxygen, etc.) move matter and energy between living organisms and the non-living environment, keeping essential nutrients available and cycling — they do not create new elements, provide food directly, or remove toxins.

Q2Which of the following is primarily responsible for warming of the Earth?

(i) Solar radiation is immediately absorbed by carbon dioxide, which then releases it as heat. (ii) The atmosphere's tiny particles absorb incoming solar radiation, which directly heats the Earth. (iii) The Earth's surface absorbs solar radiation, which is then re-radiated and trapped by greenhouse gases. (iv) The Earth's environment is heated only by the solar radiation reflected by the clouds.

Answer: (iii) The Earth's surface absorbs solar radiation, which is then re-radiated and trapped by greenhouse gases. The Earth's surface absorbs incoming sunlight and re-radiates it as infrared (heat) radiation; greenhouse gases such as CO₂, CH₄ and water vapour trap a portion of this outgoing heat in the atmosphere, keeping the planet warm — this is the natural greenhouse effect.

Q3Explain how climate change affects the water cycle. Illustrate with examples.

Climate change is disturbing the natural balance of the water cycle in several ways:

  • A warmer atmosphere can hold more moisture, so it causes heavier rainfall in some areas — such as intensified monsoons — and droughts elsewhere.
  • Melting glaciers add extra water to rivers and, in the long run, raise sea levels, threatening coastal cities such as Mumbai and Chennai.
  • Sudden bursts of intense rainfall increase surface run-off, which erodes soil, while reduced steady infiltration lowers groundwater recharge — making it harder to sustain agriculture, especially during dry months.

In this way, the water cycle links the cryosphere (glaciers), hydrosphere (rivers and oceans), atmosphere (moisture), geosphere (soil erosion, infiltration) and biosphere (crops, fisheries), and global warming affects all of them together.

Q4Describe how albedo affects the Earth's surface temperature and its climate.

Answer: albedo is the fraction of solar radiation reflected by a surface.

  • High vs low albedo: high-albedo surfaces like snow and ice (about 0.80–0.90) reflect most of the incoming sunlight and remain cool, which keeps polar regions cold. Low-albedo surfaces like black soil and ocean water absorb more radiation and heat up more quickly.
  • Ice-albedo feedback: as global warming melts highly-reflective snow and ice, it exposes darker land or ocean beneath, which absorbs more solar energy and warms further — accelerating more melting. This is one reason polar regions are warming faster than the global average.
  • Everyday examples: albedo differences also explain why dark-coloured roads/roofs get hotter than light-coloured ones, and why urban areas (with more dark, built-up surfaces) tend to be warmer than surrounding vegetated rural areas (urban heat island effect).
Q5How are mountain and valley breezes formed? Suppose there are two mountains, one covered with grass and another covered with barren rocks; would the temperature of the two mountain breezes be different? If so, how?

Formation:

  • Valley breeze (daytime): sun-facing mountain slopes heat up faster than the valley floor, so the air above the slopes becomes warm, rises, and creates a low-pressure region; cooler air from the valley moves up the slope to replace it.
  • Mountain breeze (night-time): after sunset, the situation reverses — the slopes cool faster than the valley floor, so the air over the slopes becomes cool and dense and flows down into the valley.

Grass-covered vs barren-rock mountain: yes, the mountain breezes would differ.

  • Barren rock: has a lower albedo, absorbs more heat during the day, and — having no vegetation to buffer heat exchange or provide evaporative cooling through transpiration — also loses this heat rapidly by radiation after sunset, cooling sharply. This would produce a stronger, cooler mountain breeze.
  • Grass-covered slope: is shaded and cooled somewhat during the day by transpiration, and the vegetation moderates heat loss at night, so its mountain breeze would be comparatively milder, with a smaller day–night temperature swing.
Q6You have witnessed weather phenomena, such as winds, storms, rainfall, etc. Which atmospheric layer is mainly responsible for such phenomena and what is the primary reason for its occurrence?

Answer: nearly all weather phenomena occur in the troposphere, the lowest layer of the atmosphere (average height about 12 km). This is because the troposphere is heated from below by the Earth's surface, so temperature decreases with height in this layer; the resulting warm air rises and drives convection, winds and storms. Above it, in the stratosphere, temperature increases with height (due to ozone absorbing UV radiation), which suppresses vertical mixing and confines weather to the troposphere below.

Q7Explain the processes involved in the nitrogen cycle. How would life on Earth be affected if nitrogen were not cycled?

The nitrogen cycle moves nitrogen between the atmosphere, soil, water and living organisms through these steps:

  • Nitrogen fixation: nitrogen-fixing bacteria such as Rhizobium (in root nodules of legumes) and Azotobacter (in soil), along with lightning, convert unreactive atmospheric N₂ into ammonia/nitrogen compounds that living things can use.
  • Nitrification: nitrifying bacteria such as Nitrosomonas convert ammonia into nitrite, and Nitrobacter convert nitrite into nitrate.
  • Assimilation: plants absorb nitrate/ammonia from the soil to build proteins and nucleic acids; animals obtain nitrogen by eating plants or other animals.
  • Ammonification: when organisms die or produce waste, decomposers (bacteria and fungi) break down the organic matter, returning nitrogen to the soil as ammonia.
  • Denitrification: denitrifying bacteria such as Pseudomonas convert some nitrates back into nitrogen gas, returning it to the atmosphere and completing the cycle.

If nitrogen were not cycled: atmospheric N₂ is chemically unreactive and cannot be used directly by plants or animals. Without fixation, nitrification and ammonification continually making usable nitrogen compounds available, plants would be unable to synthesise the proteins and nucleic acids essential for growth, and animals (which depend on plants, directly or indirectly, for nitrogen) would also be unable to survive — so life could not be sustained.

Q8What are the impacts of deforestation on the Earth's oxygen and carbon cycles? What are the other consequences of deforestation?

Impact on oxygen and carbon cycles: fewer trees means less photosynthesis, so less atmospheric CO₂ is absorbed and less O₂ is released. Clearing forests (by burning or decomposition) also releases the carbon that was stored in the trees back into the atmosphere as CO₂. Together, this raises atmospheric CO₂ levels and weakens a major natural carbon sink, intensifying the greenhouse effect.

Other consequences of deforestation:

  • Reduced transpiration can lead to a decline in local rainfall.
  • Changes in surface albedo, since bare land reflects/absorbs sunlight differently from forest cover.
  • Increased soil erosion, since tree roots no longer hold the soil together.
  • Loss of habitat and decline in biodiversity, as many species lose their natural homes.
Q9Explain with suitable diagram the path that carbon takes to go back to the atmosphere. You may start from plants using CO₂ from the atmosphere.

Path of carbon (fast cycle, with the slow cycle shown at the end):

  • Atmospheric CO₂ → absorbed by plants and converted to glucose (organic carbon) through photosynthesis.
  • Plants → eaten by animals; carbon passes along the food chain.
  • Plants and animals → release CO₂ back to the atmosphere through respiration.
  • Dead plants/animals → broken down by decomposers, releasing CO₂ back to the atmosphere through decomposition.
  • Some buried dead organic matter → converted over millions of years into fossil fuels (coal, oil, gas) — the slow carbon cycle.
  • Fossil fuels → burnt (combustion) for energy, releasing the stored carbon back into the atmosphere as CO₂ on a very short time scale, completing the cycle.
Simplified flow

Atmospheric CO₂ → Photosynthesis (plants) → Respiration / Decomposition / Combustion → CO₂ back to atmosphere — with the ocean also continuously exchanging CO₂ with the atmosphere, and some carbon stored long-term in fossil fuels and marine shells/sediments (refer to Fig. 13.13 in the textbook for the full schematic diagram).

Q10Why is an excess of CO₂ in the atmosphere considered undesirable even though it is required by plants?

Answer: a moderate amount of atmospheric CO₂ is essential — it is used by plants in photosynthesis and, as a greenhouse gas, helps keep the Earth warm enough for life. However, an excess of CO₂ traps far more outgoing infrared radiation than natural levels, intensifying the greenhouse effect and causing:

  • Global warming and accelerated melting of glaciers and Arctic sea ice.
  • Rising sea levels.
  • More extreme weather events.
  • Ocean acidification.

Plants cannot absorb and use this extra CO₂ fast enough to offset these harmful effects, so the damage caused by excess CO₂ far outweighs its benefit to plant growth.

Q11How is heat lost from the surface of the Earth? What is its significance?

Answer: the Earth's surface loses heat in three main ways:

  • Re-radiation of absorbed solar (mainly visible and infrared) radiation back into the atmosphere as infrared radiation.
  • Evaporation, which carries away latent heat.
  • Conduction/convection to the air above the surface.

Significance: this outgoing radiation balances the incoming solar radiation, maintaining the Earth's overall energy balance. Greenhouse gases trap part of this outgoing heat, keeping the Earth warm enough to support life; if this heat loss and its partial trapping were disrupted (too little trapped, or too much trapped), the Earth would become too cold or dangerously too hot.

Q12If the Earth were a flat disc instead of a sphere, how would the patterns of solar radiation and temperature be different?

On a sphere (real Earth): the Sun's rays strike different latitudes at different angles — concentrated over a small area near the equator and spread over a larger area near the poles — creating the equator-to-pole temperature gradient that drives global winds, ocean currents and seasons.

On a flat disc: sunlight would strike most of the sunlit face at similar, more nearly perpendicular angles, giving much more uniform heating across that face instead of the sharp equator-to-pole gradient we observe today. The familiar global wind belts, ocean current systems and seasonal patterns, which depend on the sphere's curved shape and its axial tilt, would not develop in the same way; instead, temperature differences would mainly depend on which side faced the Sun, potentially creating extreme, more abrupt contrasts between the illuminated and unilluminated sides rather than the gradual, latitude-based pattern seen on the real (spherical) Earth.

Q13Suppose there is a rise in atmospheric temperature on Earth. How would this affect the cryosphere, hydrosphere and biosphere?
  • Cryosphere: glaciers, polar ice caps and snow cover would melt faster, shrinking ice sheets and lowering the Earth's overall (average) albedo, which allows more solar energy to be absorbed — causing further warming (ice-albedo feedback).
  • Hydrosphere: meltwater would add to rivers and oceans, raising sea levels and threatening coastal areas; warmer ocean water would hold less dissolved CO₂, weakening the ocean's role as a carbon sink; changes in evaporation could intensify monsoon variability, bringing floods to some regions and drought to others.
  • Biosphere: cold-adapted species would lose habitat; warmer, more acidic seas would stress coral reefs and other marine life (coral bleaching); species distributions and migration patterns would shift; and changing rainfall patterns would affect agriculture and food chains.
Q14Explain how the Earth's atmosphere helps in maintaining a suitable temperature for life to survive on the Earth.

The atmosphere maintains a suitable temperature in two main ways:

  • It partly absorbs and reflects incoming solar radiation — the ozone layer absorbs harmful UV rays, and clouds and other gases absorb or scatter some sunlight before it reaches the surface, preventing excessive energy from reaching the Earth.
  • It traps some outgoing heat — the Earth's surface absorbs sunlight and re-radiates it as infrared radiation; greenhouse gases such as CO₂, CH₄ and water vapour absorb this re-radiated heat, preventing it from escaping directly into space.

Together, these processes keep the Earth warm enough for life to survive — without the atmosphere, the Earth would be far too cold. However, an excess of greenhouse gases from human activities intensifies this natural effect too much, causing global warming.

Q15Describe the interrelationship between different spheres of the Earth. Illustrate with example how these spheres function in a delicate balance.

The geosphere, hydrosphere, cryosphere, atmosphere and biosphere are not isolated — they constantly exchange matter and energy, so a disturbance in any one sphere causes changes in the others, maintaining (or disturbing) a delicate overall balance. For example:

  • Warmer Arabian Sea water (hydrosphere) → more evaporation → fluctuations in the southwest monsoon (atmosphere) → variability in rainfall, bringing floods to some regions of India and drought to others (further disrupting the hydrosphere).
  • The resulting rise in atmospheric temperature can also accelerate the melting of glaciers and polar ice (cryosphere), which may flood low-lying regions and, over the long run, raise sea levels that threaten coastal cities.
  • This, in turn, can disturb ecosystems within the biosphere by causing habitat loss for species that depend on stable coastlines, ice-covered regions, or specific temperature/rainfall conditions.

This chain of effects shows how the Earth functions as one connected system, in which processes such as uneven heating, water and nutrient cycling link the spheres together in a delicate balance that human activities can easily disturb.

Section E

The Journey Beyond

3 Questions
JB1Consider two hypothetical Earth-sized planets that have an atmosphere — one entirely covered by oceans and the other entirely by land. How would the wind patterns on these planets compare with the wind systems we observe on Earth?

On the real Earth, uneven heating between the equator and poles drives large-scale planetary wind belts, while the differing heating rates of land and water add local winds (land/sea breezes) and complexity, since land heats and cools much faster than water.

All-ocean planet

Water heats and cools slowly and fairly uniformly, so local land/sea breezes would not exist. The equator-to-pole temperature difference would still drive large-scale planetary wind belts (similar to Earth's Hadley, Ferrel and Polar cells), but with no continents to interrupt them, these winds and the accompanying ocean currents would likely be smoother, more zonal (running steadily around the globe) and more predictable. With abundant moisture everywhere and no landmasses to weaken storms, powerful, large storm systems (like intense hurricanes) could potentially be more frequent.

All-land planet

Land heats up and cools down quickly, so this planet would show much larger day–night and seasonal temperature swings than Earth. There would be far less atmospheric moisture (no oceans to evaporate from), so clouds and rainfall would be sparse, especially away from any water sources, and much of the interior could become desert-like. Global wind belts driven by equator-to-pole heating differences would still form, but they may be sharper and more strongly linked to rapid land temperature changes, possibly producing very strong daily convective winds.

Overall

Earth's mix of land and ocean gives rise to a more complex and varied set of wind systems (monsoons, land/sea breezes, mountain/valley breezes layered on top of global wind belts) compared to either all-ocean or all-land extremes.

JB2Choose a meal you ate recently. For each main item, explain how the carbon and nitrogen in it came from the atmosphere, and list human activities that add extra CO₂ or nitrogen to the environment.

Example meal: Roti (wheat) and Dal (lentils).

  • Carbon in roti (wheat): the wheat plant absorbed atmospheric CO₂ through its leaves and converted it, using sunlight, into glucose and then starch (through photosynthesis) — this starch is stored in the wheat grain, which is ground into flour to make roti.
  • Carbon in dal (lentils): in the same way, the lentil plant used photosynthesis to convert atmospheric CO₂ into the organic compounds stored in its seeds (the lentils/dal).
  • Nitrogen in roti (wheat): wheat is not a nitrogen-fixing plant, so it depends on nitrogen already made available in the soil — largely nitrates supplied through fertilisers manufactured by the Haber-Bosch process (or from decomposed organic matter/manure) — which the roots absorb and use to build proteins in the grain.
  • Nitrogen in dal (lentils): lentils are legumes, and their roots host nitrogen-fixing bacteria (Rhizobium) in root nodules, which convert atmospheric N₂ directly into ammonia that the plant uses to build proteins — this is why legumes generally need less nitrogen fertiliser.

Human activities adding extra CO₂/nitrogen while producing and cooking this meal:

  • Ploughing and harvesting fields using diesel-powered tractors and machinery (burns fossil fuel, releases CO₂).
  • Manufacturing nitrogenous fertilisers via the energy-intensive Haber-Bosch process, and their overuse releasing nitrous oxide and causing eutrophication of water bodies.
  • Transporting the grain/lentils to mills and markets (burns fuel, releases CO₂).
  • Processing (milling wheat into flour) using electricity, which in India is still substantially generated from fossil fuels.
  • Cooking on an LPG/gas stove burns fuel and releases CO₂ directly into the kitchen environment.
JB3Using IMD or newspaper records, find the average monsoon rainfall for your city/district for 5 years in the 1980s and 5 years in the 2020s. Note any trend and connect it to the chapter.

This is a data-collection activity — the exact answer depends on the actual figures you look up for your own city/district. Approach:

  • Visit mausam.imd.gov.in (or check local newspaper archives) and note the total June–September rainfall for 5 chosen years in the 1980s (e.g., 1981–1985) and 5 years in the 2020s (e.g., 2021–2025) for your city/district.
  • Also note the number of days each season that received heavy rain (>50 mm) in both periods.
  • Compare the two decades: has average seasonal rainfall increased, decreased, or stayed similar? Has the number of heavy-rain days changed?
Connecting to the chapter

A pattern commonly observed across many parts of India is that while total seasonal rainfall may not change hugely, the number of heavy/extreme rainfall days tends to increase — consistent with the chapter's explanation that a warmer Arabian Sea increases evaporation and moisture in the air, leading to more intense bursts of monsoon rain rather than steady, even rainfall. Changes in land use in and around a city or district (forests converted to farms or cities) reduce vegetation cover and infiltration, which can further reduce local transpiration-driven rainfall in some areas while worsening flooding and run-off from the heavy bursts that do occur.

💡 Chapter 13's core idea, in one line

The Earth works as one connected system — the geosphere, hydrosphere, cryosphere, atmosphere and biosphere constantly exchange energy and matter through uneven heating, winds, ocean currents, and the water, carbon, nitrogen and oxygen cycles, and a disturbance anywhere (like excess CO₂ from human activity) ripples through the whole system rather than staying contained in one place.

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Common Questions

Frequently Asked Questions

The atmosphere, hydrosphere, lithosphere, and biosphere continuously interact and exchange matter and energy — for example, plants (biosphere) absorb carbon dioxide from the air (atmosphere) and draw water from the soil (lithosphere/hydrosphere) during photosynthesis, while the water cycle moves water between the oceans, atmosphere, and land. No single sphere functions in isolation; a change in one usually affects the others, which is exactly why Earth is described as one interconnected system rather than four separate parts.
A moderate amount of atmospheric CO2 is essential — plants use it in photosynthesis, and as a greenhouse gas it helps keep the Earth warm enough to support life. However, an excess of CO2 traps too much heat, intensifying the greenhouse effect and driving global warming, rising sea levels, and more extreme weather, so it's the balance and quantity of CO2 that determines whether its effect is beneficial or harmful.
Yes, Earth as a System: Energy, Matter, and Life is the final chapter of the Class 9 Science 'Exploration' textbook for CBSE 2026-27, bringing together ideas from earlier chapters — energy, cycles, climate and ecosystems — into one connected view of the Earth.
WhatsApp us at +91-85952 36539 and tell us which question is causing trouble, or book a free demo class for focused, 1:1 CBSE Science coaching.
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