Class XII · Physics · Unit 2 · Walkthrough

Capacitors & Capacitance

A step-by-step walkthrough — every idea comes alive in the live panel on the right. Move through the steps; tanks fill with charge, plates squeeze closer, sponges soak up field, and capacitors charge and discharge through a resistor before your eyes.

1 — What a capacitor is

A capacitor is two conducting plates separated by an insulator. Connect a battery and one plate piles up +Q, the other an equal −Q; the device stores charge and electrical energy.

Picture a water tank: the battery's voltage is the water pressure, the charge is the water stored. A bigger pressure (V) pushes in more water (Q), and a wider tank holds more water per unit pressure — that "wideness" is the capacitance C.

Definition of capacitanceQ = C V → C = Q / V
unit: farad (F) = 1 coulomb per volt · 1 µF = 10⁻⁶ F

Exam point: capacitance is a fixed property of the plates' shape and spacing — it does not change when you change V; Q just adjusts so that Q/V stays the same.

2 — Capacitance & geometry

For two parallel plates of area A a distance d apart in vacuum, capacitance depends only on geometry:

Parallel-plate capacitorC = ε₀ A / d
ε₀ = 8.85 × 10⁻¹² F·m⁻¹ (permittivity of free space)

Bigger area A — more room for charge to spread → C increases.
Smaller gap d — plates pull harder on each other's charge → C increases.

worked — a small capacitor

A = 0.02 m², d = 1 mm, vacuum?

C = (8.85×10⁻¹² × 0.02) / 0.001 = 1.77 × 10⁻¹⁰ F ≈ 177 pF

3 — Dielectrics

Slide an insulator — a dielectric — between the plates and the capacitance jumps. The dielectric's molecules polarise, partly cancelling the field, so the same voltage now stores more charge.

With a dielectricC = εᵣ ε₀ A / d
εᵣ = relative permittivity (dielectric constant)
air ≈ 1 · paper ≈ 3.7 · mica ≈ 6 · water ≈ 80

Think of a dry sponge dropped into the tank: it soaks up field and lets you pack far more charge into the same space — that is why every practical capacitor has a dielectric filling.

Bonus: the dielectric also lets the plates sit closer without sparking, so C rises for two reasons at once.

4 — Capacitors in parallel

Connect capacitors side by side across the same two wires and every one feels the same voltage V. The total charge is the sum, so the capacitances simply add.

Parallel combinationsame V across each · Q_total = Q₁ + Q₂ + …
C_parallel = C₁ + C₂ + C₃ + … (always BIGGER)

Like placing two water tanks next to each other under one pressure pipe: their storage volumes add directly — parallel always gives more total capacitance.

worked — adding up

2 µF parallel with 3 µF?

C = 2 + 3 = 5 µF

5 — Capacitors in series

Connect capacitors in a chain and the same charge Q sits on every one, while the battery's voltage splits between them. The reciprocals add, so the combined capacitance is smaller than the smallest.

Series combinationsame Q on each · V_total = V₁ + V₂ + …
1/C_series = 1/C₁ + 1/C₂ + … (always SMALLER)
two only: C = (C₁C₂)/(C₁+C₂)

worked — chain of two

2 µF in series with 3 µF?

C = (2×3)/(2+3) = 6/5 = 1.2 µF — smaller than both

Why? Series effectively increases the total plate gap d, and C ∝ 1/d, so the combination falls.

6 — Energy stored

Charging a capacitor takes work, pushing charge against the growing voltage. That work is stored in the electric field and can be released in an instant — a bright spark.

Energy storedE = ½ C V² = ½ Q V = Q² / (2C)
measured in joules (J)

Because the energy goes as V squared, doubling the voltage stores four times the energy — which is exactly why a camera flash charges to a high voltage before firing.

worked — the spark

100 µF charged to 200 V?

E = ½ × 100×10⁻⁶ × 200² = 2.0 J dumped in a flash

7 — Charging through a resistor

Put a resistor in the path and the capacitor cannot fill instantly. The voltage rises fast at first, then ever more slowly as it approaches the battery voltage — an exponential curve.

Charging an RC circuitV(t) = V₀ (1 − e^(−t/RC))
time constant τ = R C (seconds)
after one τ: ~63% full · after 5τ: ~99% full

Like filling a tank through a narrow tap: a near-empty tank fills quickly, but as it nears the top the back-pressure rises and the inflow tapers off.

8 — Discharging through a resistor

Disconnect the battery and let the capacitor empty through the resistor: the voltage falls quickly at first, then trails off, a mirror image of charging.

Discharging an RC circuitV(t) = V₀ e^(−t/RC)
after one τ: down to ~37% · after 5τ: essentially empty

This steady, predictable drain is the heartbeat of timers and the smooth fade of camera-flash recharge lights — change R or C and you tune exactly how long it takes.

9 — Recap & applications

You have walked through the whole story of capacitors — from a single pair of plates to charging and discharging through a resistor.

Camera flash — a capacitor charges slowly, then dumps E = ½CV² into the bulb as a brilliant burst.
Power-supply smoothing — large capacitors fill in the dips between AC peaks, giving steady DC.
Defibrillator — stores a big charge, then releases it through the heart in a controlled jolt.

Q = C V; capacitance is measured in farads (C/V) and is fixed by geometry.
Parallel-plate: C = ε₀A/d — bigger area or smaller gap raise C.
A dielectric multiplies C by εᵣ: C = εᵣε₀A/d.
Parallel: C = C₁ + C₂ (bigger). Series: 1/C = 1/C₁ + 1/C₂ (smaller).
Stored energy E = ½CV² = ½QV = Q²/2C.
Charging V = V₀(1 − e^(−t/RC)); discharging V = V₀e^(−t/RC); τ = RC.

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