Magnetism and Electromagnetic Induction

Subject: Physics
Topic: 7
Cambridge Code: 0625

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Magnetic Fields

Magnetic field - Region where magnetic force acts

Field Representation

Magnetic field lines:

• Direction: North to South pole (outside magnet)
• Density indicates field strength
• Never cross

Unit: Tesla (T) = kilograms/(Ampere·second²)

Magnetic Flux Density

$B = \frac{F}{IL}$

Where:

• F = force
• I = current
• L = length of conductor

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Forces on Current-Carrying Conductors

Force on conductor in magnetic field:

$F = BIL\sin θ$

Where:

• B = magnetic flux density
• I = current
• L = length of conductor
• θ = angle between B and L

Maximum force: θ = 90° (perpendicular) $F = BIL$

Zero force: θ = 0° or 180° (parallel or antiparallel)

Direction (Fleming's Left-Hand Rule)

Thumb: Force direction First finger: Field direction Second finger: Current direction

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Charges in Magnetic Fields

Force on moving charge:

$F = Bqv\sin θ$

Where:

• q = charge
• v = velocity
• θ = angle between B and v

Circular Motion

Magnetic force provides centripetal force:

$Bqv = \frac{mv^2}{r}$

$r = \frac{mv}{Bq}$

Radius depends on:

• Mass: Heavier → larger radius
• Velocity: Faster → larger radius
• B-field: Stronger → smaller radius
• Charge: Larger → smaller radius

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Electromagnetic Induction

Faraday's Law

$ε = -N\frac{\Delta Φ}{Δt}$

Where:

• ε = induced e.m.f.
• N = number of turns
• Φ = magnetic flux
• ΔΦ/Δt = rate of flux change

Magnetic Flux

$Φ = BA\cos θ$

Where:

• B = magnetic flux density
• A = area
• θ = angle between B and area normal

Causes of Induced E.m.f.

1. Change in B: Stronger or weaker field
2. Change in area: Larger or smaller loop
3. Change in angle: Rotating coil or moving magnet
4. Motion: Moving wire through field

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Lenz's Law

Induced current opposes the change causing it

$ε = -N\frac{\Delta Φ}{Δt}$

Negative sign indicates opposition

Applications

Generator: Motional e.m.f. when coil rotates in B-field Motor: Magnetic force on current-carrying coil in B-field Transformer: Changing flux induces voltage in secondary coil

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AC Generators

Rotating coil in magnetic field generates alternating e.m.f.

$ε = ε_0\sin(ωt)$

Where:

• ε₀ = peak e.m.f.
• ω = angular frequency
• ε₀ = NBAω (maximum when coil perpendicular to field)

Graph

Sine wave:

• Peak values: ±ε₀
• Period: T = 2π/ω
• Frequency: f = ω/2π

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Transformers

Transformer - Changes voltage using electromagnetic induction

Principle

Changing current in primary coil:

• Creates changing magnetic field
• Induces voltage in secondary coil

Transformer Equation

$\frac{V_s}{V_p} = \frac{N_s}{N_p}$

Where:

• V_p = primary voltage
• V_s = secondary voltage
• N_p = primary turns
• N_s = secondary turns

Step-up transformer: $N_s > N_p$, $V_s > V_p$ Step-down transformer: $N_s < N_p$, $V_s < V_p$

Power Relationship

Ideal transformer (no losses): $P_p = P_s$ $V_pI_p = V_sI_s$

Current relationship: $\frac{I_s}{I_p} = \frac{N_p}{N_s}$

High voltage → low current Low voltage → high current

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Alternating Current

A.C. - Current changes direction periodically

$I = I_0\sin(ωt)$

Where:

• I₀ = peak current
• ω = angular frequency

RMS Values

Root Mean Square - Effective value

$I_{\text{rms}} = \frac{I_0}{\sqrt{2}} ≈ 0.707I_0$

$V_{\text{rms}} = \frac{V_0}{\sqrt{2}}$

Power with A.C.: $P = I_{\text{rms}}V_{\text{rms}}$

(Uses RMS values, not peak)

Frequency

UK: 50 Hz US: 60 Hz Period: T = 1/f = 20 ms (UK)

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AC in Different Components

Resistor

Always carries current:

• Voltage and current in phase
• $P = I_{\text{rms}}^2R$

Inductor (Coil)

Opposes change in current:

• Current lags voltage by 90°
• Inductive reactance: $X_L = ωL$
• Power: $P = 0$ (ideal)

Capacitor

Opposes change in voltage:

• Current leads voltage by 90°
• Capacitive reactance: $X_C = \frac{1}{ωC}$
• Power: $P = 0$ (ideal)

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Solenoid and Electromagnet

Solenoid - Coil of wire

Magnetic field: $B = μ_0\frac{NI}{L}$

Where:

• μ₀ = permeability of free space
• N = number of turns
• I = current
• L = length

Applications:

• Electromagnets
• Relays
• Motors
• Inductors

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Key Points

1. Magnetic force perpendicular to field and current
2. Induced e.m.f. from changing magnetic flux
3. Lenz's law: Induced effect opposes change
4. Transformer equation: V_s/V_p = N_s/N_p
5. Ideal transformer: Power in = Power out
6. A.C. has RMS and peak values
7. RMS = peak/√2 for sine waves
8. Generators produce A.C. from rotating coil
9. Solenoid field strength ∝ NI/L
10. Induction used in transformers, motors, generators

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Practice Questions

1. Calculate magnetic force
2. Find radius in magnetic field
3. Apply Faraday's law
4. Use Lenz's law
5. Determine induced e.m.f.
6. Calculate transformer ratios
7. Find secondary voltage/current
8. Calculate power with A.C.
9. Analyze A.C. circuits
10. Solenoid field calculations

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Revision Tips

• Use Fleming's rules correctly
• Understand Lenz's law concept
• Know transformer equations
• Use RMS values for A.C. power
• Distinguish peak and RMS
• Understand induction principle
• Know generator/motor operation
• Draw field line diagrams
• Visualize motion effects