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CBSE Class 12 Physics★ 3-5 marks · CBSE Class 12 Physics Chapter 8; spectrum and EM wave properties feature in JEE and NEET

Electromagnetic Waves

LIGHT is an electromagnetic wave — a TRAVELLING oscillation of electric and magnetic fields. This chapter introduces displacement current, the electromagnetic spectrum, and the properties of EM waves. CBSE Class 12 Physics Chapter 8.

⏱ 14 min readMedium difficulty✓ Free · NCERT-aligned

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

1Explain displacement current and the Ampere-Maxwell law
2State Maxwell's equations qualitatively
3Describe the properties of electromagnetic waves
4Relate E0, B0, intensity, and the Poynting vector
5Order the electromagnetic spectrum and its applications

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Why this chapter matters

Light, radio waves, and X-rays are all electromagnetic waves differing only in frequency. Maxwell's displacement current, the properties of EM waves, and the electromagnetic spectrum unify electricity, magnetism, and optics and underpin all modern communication and imaging.

Before you start — revise these

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

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Class 12 Physics: Electromagnetic Induction

Changing fields and induced effects

Electromagnetic Waves

'Light, radio waves, X-rays — they are ALL electromagnetic waves. The only difference is the FREQUENCY.'

1. Chapter Overview

This chapter introduces ELECTROMAGNETIC (EM) WAVES — self-propagating oscillations of electric and magnetic fields. Topics include: the CONCEPT OF DISPLACEMENT CURRENT (the crucial term Maxwell added to Ampere's law), MAXWELL'S EQUATIONS (the complete set), the nature of EM WAVES (transverse, speed = c in vacuum), and the ELECTROMAGNETIC SPECTRUM (from radio waves to gamma rays).

2. Displacement Current

Displacement current: I_d = ε₀ dΦ_E/dt.
'Maxwell realised that a CHANGING electric field can also produce a magnetic field — just like a current does.'
Total current: I_total = I_cond + I_d = I_c + ε₀ dΦ_E/dt.
Ampere-Maxwell law: ∮ B·dl = μ₀(I_c + ε₀ dΦ_E/dt).

'Without displacement current, a charging capacitor would break Ampere's law — the magnetic field around the wire would have no continuation across the capacitor plates. Displacement current SAVES the law.'

3. Maxwell's Equations (Integral Form)

Law	Equation	Meaning
Gauss (Electric)	∮ E·dA = q/ε₀	Electric flux = charge enclosed
Gauss (Magnetic)	∮ B·dA = 0	No magnetic monopoles
Faraday	∮ E·dl = −dΦ_B/dt	Changing B induces E
Ampere-Maxwell	∮ B·dl = μ₀(I + ε₀ dΦ_E/dt)	Current AND changing E produce B

'Maxwell's equations are the COMPLETE LAWS of electromagnetism — they describe ALL electrical and magnetic phenomena.'

4. Properties of Electromagnetic Waves

Wave Equation

Electromagnetic waves are produced by ACCELERATING CHARGES.
Speed: c = 1/√(μ₀ε₀) = 3×10⁸ m/s in vacuum.

Key Properties

Transverse: E and B are PERPENDICULAR to each other and to the direction of propagation.
E and B are in phase: They reach maxima and minima TOGETHER.
Speed: v = c/n in a medium (n = refractive index).
Energy density: u = ½ε₀E² + B²/(2μ₀) = ε₀E² (since E = cB, both terms are equal).

Energy Transport — Poynting Vector

S⃗ = (1/μ₀)(E⃗ × B⃗) — the energy flux per unit area.
Intensity: I = S_avg = ½ c ε₀ E₀² = c B₀²/(2μ₀).

Worked Example 1

Problem: An EM wave has E₀ = 100 V/m. Find B₀ and the average intensity. Solution: B₀ = E₀/c = 100/(3×10⁸) = 3.33×10⁻⁷ T. I = ½ c ε₀ E₀² = 0.5 × 3×10⁸ × 8.85×10⁻¹² × 10⁴ = 13.275 W/m².

5. Electromagnetic Spectrum

Type	Wavelength Range	Frequency Range	Source	Applications
Radio waves	> 0.1 m	< 3×10⁹ Hz	Accelerating charges in antenna	Broadcasting, communication
Microwaves	1 mm to 0.1 m	3×10⁹ to 3×10¹¹ Hz	Klystron, magnetron	Radar, microwave oven
Infrared (IR)	700 nm to 1 mm	3×10¹¹ to 4.3×10¹⁴ Hz	Hot bodies	Remote control, thermal imaging
Visible light	400 nm to 700 nm	4.3×10¹⁴ to 7.5×10¹⁴ Hz	Sun, incandescent sources	Human vision
Ultraviolet (UV)	10 nm to 400 nm	7.5×10¹⁴ to 3×10¹⁶ Hz	Sun, arc lamps	Sterilisation, vitamin D production
X-rays	0.01 nm to 10 nm	3×10¹⁶ to 3×10¹⁹ Hz	X-ray tubes	Medical imaging, crystallography
Gamma rays	< 0.01 nm	> 3×10¹⁹ Hz	Radioactive nuclei	Cancer treatment, astronomy

Key Facts About the EM Spectrum

'All EM waves travel at the SAME speed in vacuum — 3×10⁸ m/s.'
Frequency and wavelength are INVERSELY related: c = fλ.
Higher frequency = higher energy: E = hf.
The atmosphere is TRANSPARENT to visible light and some radio waves — opaque to most UV, IR, and gamma rays.

6. Applications of Different EM Waves

Radio Waves

AM (Amplitude Modulation): 530-1710 kHz. FM (Frequency Modulation): 88-108 MHz.
'Radio waves have the LOWEST frequency — they bend around obstacles (diffraction) and travel long distances.'

Microwaves

'Microwaves are absorbed by WATER molecules — that is how a microwave oven heats food.'
Used in RADAR (Radio Detection And Ranging).

Infrared

'Every object above absolute zero emits infrared radiation. Thermal imaging cameras detect IR to "see" heat.'

X-rays

'X-rays pass through soft tissue but are ABSORBED by bones — creating the familiar medical image.'
Danger: Ionising radiation — can damage DNA.

7. Common Mistakes

Speed of EM waves depends on medium: In vacuum, c = 3×10⁸ m/s ALWAYS. In a medium, v = c/n < c.
E and B relationship: E₀ = cB₀ (in vacuum). NOT E₀ = B₀ or E₀ = c²B₀.
Direction of energy flow: The Poynting vector S = (1/μ₀)E×B gives the direction of energy propagation — NOT the direction of E or B alone.
Frequency does NOT change: When an EM wave enters a different medium, frequency REMAINS SAME, wavelength changes (λ = v/f).

8. CBSE Exam Focus

Displacement current — concept, I_d = ε₀ dΦ_E/dt
Maxwell's equations — qualitative understanding, the 'correction' to Ampere's law
Properties of EM waves — transverse, E ⊥ B, E₀ = cB₀, speed in vacuum
Electromagnetic spectrum — order of wavelengths/frequencies, sources, applications
Energy of EM waves — Poynting vector, intensity formula

9. Self-Test

Q1: A capacitor with plates of area 0.01 m² and separation 1 mm is being charged at 2 A. Find the displacement current. A1: I_d = I_c = 2 A. 'Displacement current between the plates EQUALS the conduction current in the wires.'

Q2: An EM wave has frequency 10¹⁰ Hz. Find its wavelength in air. A2: λ = c/f = 3×10⁸/10¹⁰ = 0.03 m = 3 cm (microwave region).

Q3: An EM wave has B₀ = 10⁻⁶ T. Find E₀ and the average intensity. A3: E₀ = cB₀ = 3×10⁸×10⁻⁶ = 300 V/m. I = cB₀²/(2μ₀) = (3×10⁸×10⁻¹²)/(2×4π×10⁻⁷) = (3×10⁻⁴)/(2.51×10⁻⁶) ≈ 119.5 W/m².

Q4: Arrange in increasing order of wavelength: X-rays, visible light, radio waves, IR. A4: X-rays < visible < IR < radio waves. 'Higher frequency → shorter wavelength → higher energy.'

Q5: A 100 W bulb emits EM radiation. At a distance of 1 m, what is the intensity? (Assume spherical emission.) A5: I = P/(4πr²) = 100/(4π×1) = 100/12.57 = 7.96 W/m².

10. Conclusion

Electromagnetic waves are the UNIFICATION of electricity, magnetism, and optics:

MAXWELL: 'He predicted EM waves — and showed that LIGHT IS AN EM WAVE.'
SPECTRUM: 'Seven regions — but the physics is the SAME. Only the frequency (and therefore energy) changes.'
ENERGY: 'EM waves carry energy through empty space — the Sun's light travels 150 million km to warm the Earth.'
APPLICATIONS: 'From radio to gamma rays — every frequency range has found a use in technology and medicine.'

'Electromagnetic waves are the most versatile of all physical phenomena — they carry information, energy, and the very light by which we see the universe.'

Key formulas & results

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

Displacement current

I_d = epsilon0 dPhi_E/dt

A changing electric field acts like a current.

Speed of EM waves

c = 1/sqrt(mu0 epsilon0) = 3e8 m/s; E0 = c B0

E and B are perpendicular and in phase.

Intensity

I = (1/2) c epsilon0 E0^2 = c B0^2/(2 mu0)

Poynting vector S = (1/mu0)(E x B).

Wave relation

c = f lambda; E = h f

Frequency stays constant across media; wavelength changes.

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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

✗ Thinking EM waves travel at c in all media

✓ Speed is c only in vacuum; in a medium v = c/n is slower.

WATCH OUT

✗ Misremembering the E-B relation

✓ In vacuum E0 = c B0, not E0 = B0 or E0 = c^2 B0.

WATCH OUT

✗ Saying frequency changes in a new medium

✓ Frequency stays the same when an EM wave enters a new medium; the wavelength changes.

WATCH OUT

✗ Confusing the Poynting vector with E or B direction

✓ S = (1/mu0)(E x B) gives the direction of energy flow, perpendicular to both E and B.

NCERT exercises (with solutions)

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

Displacement current and Maxwell

Displacement current and Ampere-Maxwell law

Questions

EM wave properties

Transverse nature, speed, E-B relation, intensity

Questions

EM spectrum

Order, sources, and applications

Questions

Practice problems

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

Q1EASY· Displacement Current

A capacitor is charged at 2 A. Find the displacement current between its plates.

▶ Show solution

The displacement current equals the conduction current, so I_d = 2 A.

Q2EASY· Wave Relation

An EM wave has frequency 1e10 Hz. Find its wavelength in air.

▶ Show solution

lambda = c/f = 3e8/1e10 = 0.03 m = 3 cm (microwave region).

Q3MEDIUM· Intensity

An EM wave has B0 = 1e-6 T. Find E0 and the average intensity.

▶ Show solution

E0 = c B0 = 3e8 x 1e-6 = 300 V/m. I = c B0^2/(2 mu0) = (3e8 x 1e-12)/(2 x 4 pi e-7) approximately 119.5 W/m^2.

Q4EASY· Spectrum

Arrange in increasing wavelength: X-rays, visible light, radio waves, IR.

▶ Show solution

X-rays < visible < IR < radio waves (higher frequency means shorter wavelength).

Q5MEDIUM· Intensity

A 100 W bulb emits uniformly. Find the intensity at 1 m.

▶ Show solution

I = P/(4 pi r^2) = 100/(4 pi x 1) = 7.96 W/m^2.

5-minute revision

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

•Displacement current I_d = epsilon0 dPhi_E/dt completes Ampere's law.
•Maxwell's four equations describe all electromagnetism.
•EM waves are transverse with E perpendicular to B and to propagation.
•c = 1/sqrt(mu0 epsilon0) = 3e8 m/s; E0 = c B0; E and B in phase.
•Intensity I = (1/2) c epsilon0 E0^2; Poynting vector gives energy flow.
•Spectrum (increasing frequency): radio, microwave, IR, visible, UV, X-ray, gamma.
•Frequency is constant across media; wavelength and speed change.

CBSE marks blueprint

Where the marks come from in this chapter — so you can plan your prep.

Typical chapter weightage: 3-5 marks across the chapter

Question type	Marks each	Typical count	What it tests
EM spectrum	2-3	1	Order, sources, applications
Wave properties / intensity	2-3	1	E-B relation, speed, intensity
Displacement current	1-2	1	Concept and Ampere-Maxwell law

Prep strategy

Understand why Maxwell added displacement current
Memorise EM wave properties and E0 = cB0
Learn the spectrum order with sources and uses
Practise intensity and wavelength numericals

Where this shows up in the real world

This chapter isn't just an exam topic — it lives in the world around you.

Communication

Radio waves and microwaves carry radio, TV, mobile, and satellite signals.

Medicine

X-rays image bones and gamma rays treat cancer.

Everyday technology

Microwave ovens, remote controls (IR), and sterilisation (UV) all use specific EM bands.

Exam strategy

Battle-tested tips from teachers and toppers for this chapter.

Explain displacement current with the charging-capacitor example
State EM wave properties precisely (E0 = cB0)
Memorise the spectrum order and applications
Use intensity formulas with correct constants

Going beyond the textbook

For olympiad aspirants and curious learners — topics that build on this chapter.

Derive the wave equation from Maxwell's equations.
Analyse radiation pressure and momentum carried by EM waves.

Where else this chapter is tested

CBSE board isn't the only one — other exams test this chapter too.

CBSE Class 12 Physics examMedium

JEE Main (EM Waves)Medium

NEET PhysicsMedium

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Questions students ask

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

Ampere's original law related the magnetic field around a loop to the conduction current passing through it. But consider a charging capacitor: a conduction current flows in the wires, yet no charge crosses the gap between the plates, so Ampere's law gave inconsistent results depending on the surface chosen. Maxwell resolved this by noting that the changing electric field between the plates is equivalent to a current, the displacement current I_d = epsilon0 dPhi_E/dt. Adding this term makes the law consistent and, crucially, predicts that changing electric fields generate magnetic fields, leading to electromagnetic waves.

Radio waves, microwaves, infrared, visible light, ultraviolet, X-rays, and gamma rays are all electromagnetic waves consisting of oscillating electric and magnetic fields. They all travel at the same speed c in vacuum and obey the same Maxwell's equations. The only difference between them is their frequency (and hence wavelength and photon energy E = hf). This is why the entire range is called a single electromagnetic spectrum, even though the waves are produced by different sources and have very different applications.

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