Chapter 11 of 12

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Haryana (BSEH)Class 9 Mathematics★ 7 marks · CBSE Class 9 board (high-yield)

Surface Areas and Volumes

Formulas for the surface area and volume of cuboids, cubes, cylinders, cones, spheres and hemispheres — and how to mix and match them in composite-solid problems.

⏱ 14 min readEasy difficulty✓ Free · NCERT-aligned

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

1Recall the CSA, TSA, volume and diagonal formulas for cuboid and cube
2Apply the cylinder, cone, sphere and hemisphere formulas to direct problems
3Compute the slant height of a cone using ℓ = √(r² + h²)
4Decompose composite solids (cone-on-hemisphere, cylinder-with-hemispheres) and find total exposed surface area
5Use volume conservation in melting / recasting problems

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Why this chapter matters

Mensuration is the single highest-mark, lowest-skill chapter in Class 9. Memorise the formulas and you bank guaranteed marks. The same formulas appear in Class 10 'Surface Areas and Volumes', so the work compounds.

Before you start — revise these

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

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Mensuration (Class 8)

Cube, cuboid, cylinder formulas — building on this

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Heron's Formula

Triangle area as one component of 3D faces

Surface Areas and Volumes

This chapter is a formula-heavy mensuration chapter. Memorise the table once and the problems become arithmetic. Common 4-mark question: a composite shape (e.g. cylinder + hemisphere). The trick is knowing exactly which surfaces are exposed.

1. The complete formula sheet

For all formulas, $π \approx \frac{22}{7}$ unless stated.

Cuboid (length $l$ , breadth $b$ , height $h$ )

$Lateral surface area (LSA) = 2 h (l + b)$ $Total surface area (TSA) = 2 (l b + bh + h l)$ $Volume = l bh$ $Diagonal = l^{2} + b^{2} + h^{2}$

Cube (side $a$ )

$LSA = 4 a^{2}, TSA = 6 a^{2}, Volume = a^{3}, Diagonal = a 3$

Right circular cylinder (radius $r$ , height $h$ )

$Curved surface area (CSA) = 2 π r h$ $TSA = 2 π r (r + h)$ $Volume = π r^{2} h$

Right circular cone (radius $r$ , height $h$ , slant $ℓ$ )

$ℓ = r^{2} + h^{2}$ $CSA = π r ℓ$ $TSA = π r (r + ℓ)$ $Volume = \frac{1}{3} π r^{2} h$

Sphere (radius $r$ )

$Surface area = 4 π r^{2}$ $Volume = \frac{4}{3} π r^{3}$

Hemisphere (radius $r$ )

$CSA = 2 π r^{2}$ $TSA = 3 π r^{2} (adds the flat circular face)$ $Volume = \frac{2}{3} π r^{3}$

2. Worked example — cylinder

A cylindrical pillar has radius 0.7 m and height 4 m. Find the curved surface area and volume.

CSA $= 2 π r h = 2 \times \frac{22}{7} \times 0.7 \times 4 = 17.6$ m².

Volume $= π r^{2} h = \frac{22}{7} \times 0.49 \times 4 = 6.16$ m³.

3. Worked example — composite shape

A toy is in the shape of a cone mounted on a hemisphere. Both have the same radius 3 cm, and the cone's height is 4 cm. Find the total surface area.

The exposed surfaces are:

The cone's curved surface (not the base — it's joined to the hemisphere).
The hemisphere's curved surface (not the flat face — it's joined to the cone).

Cone slant $ℓ = 3^{2} + 4^{2} = 5$ .

$CSA_{cone} = π r ℓ = π \times 3 \times 5 = 15 π$ . $CSA_{hemisphere} = 2 π r^{2} = 2 π \times 9 = 18 π$ .

Total $= 33 π \approx 103.7$ cm².

4. The "conservation of volume" trick

When you melt one solid and recast it as another, volume is conserved (mass = volume × density and density is unchanged).

Example. A solid cylindrical iron rod of radius 2 cm and height 16 cm is melted and recast into a sphere. Find the sphere's radius.

$π r_{cyl}^{2} h = \frac{4}{3} π r_{sph}^{3}$ $π \cdot 4 \cdot 16 = \frac{4}{3} π r^{3}$ $r^{3} = \frac{3 \cdot 64}{4} = 48 \Rightarrow r = 348 \approx 3.63 cm .$

5. Tips for marks

Always state the formula first before substituting. Examiners give 1 mark for the formula alone.
Mind the units. Convert everything to the same unit before computing. Volume answers go in cm³ or m³.
For composite shapes, draw a sketch and mark which surfaces are exposed. The figure earns 1 mark.

What's next

Statistics — the final chapter — switches gears entirely into data: mean, median, mode, bar graphs, histograms and frequency polygons.

Key formulas & results

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

Cube

TSA = 6a², Volume = a³, Diagonal = a√3

Cuboid

TSA = 2(lb + bh + hl), Volume = lbh, Diagonal = √(l²+b²+h²)

Cylinder (CSA)

CSA = 2πrh

Just the curved face.

Cylinder (TSA)

TSA = 2πr(r + h)

CSA + 2 circular ends.

Cylinder volume

V = πr²h

Cone slant

ℓ = √(r² + h²)

Cone CSA

CSA = πrℓ

Cone TSA

TSA = πr(r + ℓ)

Cone volume

V = (1/3)πr²h

1/3 of the corresponding cylinder.

Sphere

SA = 4πr²,  V = (4/3)πr³

Hemisphere CSA

CSA = 2πr²

Hemisphere TSA

TSA = 3πr²

Adds the flat circular face.

Hemisphere V

V = (2/3)πr³

Half a sphere.

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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

✗ Confusing CSA (curved) with TSA (total)

✓ CSA = only the curved surface; TSA includes the flat ends. Read the question — 'curved' vs 'total' is a 1-mark trap.

WATCH OUT

✗ Using the WRONG π — sometimes 22/7, sometimes 3.14

✓ Use whichever value the question specifies. If unspecified, default to 22/7. Be consistent within one calculation.

WATCH OUT

✗ Adding ALL surfaces of a composite shape without excluding the join

✓ For a hemisphere on top of a cylinder, exclude the cylinder's top circle AND the hemisphere's flat face — they're sealed together.

WATCH OUT

✗ Mismatched units (cm and m mixed)

✓ Convert everything to one unit BEFORE plugging into the formula. 1 m = 100 cm, 1 m² = 10000 cm², 1 m³ = 1,000,000 cm³.

NCERT exercises (with solutions)

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

Ex 11.1

Exercise 11.1

Right circular cone — CSA, TSA, volume; slant computation

Questions

Ex 11.2

Exercise 11.2

Sphere and hemisphere — SA and volume problems

Questions

Ex 11.3

Exercise 11.3

Mixed composite-solid problems and melting / recasting

Questions

Practice problems

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

Q1EASY· Cylinder

Find the CSA of a cylinder with radius 3.5 cm and height 10 cm. (Use π = 22/7.)

▶ Show solution

CSA = 2πrh = 2 × 22/7 × 3.5 × 10 = 220 cm².

Q2EASY· Sphere

Find the volume of a sphere of radius 7 cm.

▶ Show solution

V = (4/3)πr³ = (4/3) × 22/7 × 343 = 4312/3 ≈ 1437.3 cm³.

Q3MEDIUM· Cone

A cone has height 12 cm and radius 5 cm. Find its slant height and TSA.

▶ Show solution

ℓ = √(5² + 12²) = 13 cm. TSA = πr(r + ℓ) = π × 5 × 18 = 90π ≈ 282.86 cm².

Q4MEDIUM· Composite

A solid is a cylinder (radius 7 cm, height 10 cm) with a hemisphere of the same radius on top. Find total surface area.

▶ Show solution

Exposed: cylinder's curved + cylinder's bottom + hemisphere's curved. = 2πr·h + πr² + 2πr² = 2π(7)(10) + π(49) + 2π(49) = 140π + 49π + 98π = 287π ≈ 901.71 cm².

Q5HARD· Recasting

A metallic sphere of radius 10.5 cm is melted and recast into small cones of radius 3.5 cm and height 3 cm. How many cones?

▶ Show solution

V_sphere = (4/3)π(10.5)³ = 4851π cm³. V_cone = (1/3)π(3.5)²(3) = 12.25π cm³. Number = 4851π / 12.25π = 396 cones.

5-minute revision

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

•Cube: TSA = 6a², V = a³, diagonal = a√3.
•Cuboid: TSA = 2(lb+bh+hl), V = lbh.
•Cylinder: CSA = 2πrh, TSA = 2πr(r+h), V = πr²h.
•Cone: ℓ = √(r²+h²), CSA = πrℓ, V = (1/3)πr²h.
•Sphere: SA = 4πr², V = (4/3)πr³.
•Hemisphere: CSA = 2πr², TSA = 3πr², V = (2/3)πr³.
•Volume is conserved in melting / recasting problems.
•For composites, exclude the joined faces.

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Questions students ask

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

About 7 marks of Unit V (Mensuration), which itself is 13 marks. Expect at least one 3-mark and one 4-mark question.

Use whichever the question specifies. If unspecified, default to 22/7 (gives clean integer answers for typical problem values like 7, 14, 21).

No — frustums are Class 10. Class 9 covers only the basic six solids.

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