Chapter 3 / 3.10 Cells, EMF, Internal Resistance

⚡ Big Picture

Electric circuits need a steady energy source. A cell (chemical battery) supplies that energy, letting current flow and heat up a resistor. The power lost as heat in any resistor is
\(P = I^2 R = \dfrac{V^2}{R}\) 🔥:contentReference[oaicite:0]{index=0}

🔋 Anatomy of a Cell

Electrodes: Positive (P) and negative (N) plates dipped in an electrolyte.
Electromotive Force (emf) \( \varepsilon\): The open-circuit potential difference between P and N:
\( \varepsilon = V_{+} + V_{-} \) 😀:contentReference[oaicite:1]{index=1}
Internal Resistance \(r\): The electrolyte itself resists current.

🔌 Cell in a Circuit

Connect a resistor \(R\) across the cell. Current flows from P ➜ N outside, but through the electrolyte it goes from N ➜ P. The terminal voltage you measure is lower than the emf because some energy is lost inside the cell:

Terminal voltage: \( V = \varepsilon – I\,r \):contentReference[oaicite:2]{index=2}
Ohm’s law for the external resistor: \( V = I\,R \):contentReference[oaicite:3]{index=3}
Current delivered: \( I = \dfrac{\varepsilon}{R + r} \) (combine the two equations):contentReference[oaicite:4]{index=4}
Maximum possible current: when \(R=0\), \( I_{\text{max}} = \dfrac{\varepsilon}{r} \) (never draw this continuously — it damages the cell!):contentReference[oaicite:5]{index=5}

🔗 Combining Cells in Series

Put two cells end-to-end, positive to negative (standard series connection). The pair behaves like one bigger cell with

\[ \boxed{\varepsilon_{\text{eq}} = \varepsilon_1 + \varepsilon_2},\qquad \boxed{r_{\text{eq}} = r_1 + r_2} \]:contentReference[oaicite:6]{index=6}

In words: emfs add, internal resistances add. More cells in series ➜ higher voltage but also higher “built-in” resistance.

📡 Why High-Voltage Transmission?

Sending electric power \(P\) over long cables of resistance \(R_c\) wastes energy: \(P_c = I^2R_c\). For the same power, raising the transmission voltage \(V\) lets you lower the current \(I\), and the wasted power falls with \(1/V^{2}\). That’s why power lines carry scary-high voltages ⚠️:contentReference[oaicite:7]{index=7}

🎯 NEET High-Yield Nuggets

Relationship \(V = \varepsilon – I\,r\) and the allied current formula \(I=\varepsilon/(R+r)\).
Open-circuit vs closed-circuit voltage: emf is measured only when \(I = 0\).
Maximum safe current depends on internal resistance: \(I_{\text{max}} = \varepsilon/r\).
Series combination rules: emfs add, internal resistances add.
Power loss minimization trick: transmit at high voltage to keep \(I\) (and \(I^{2}R\) losses) low.

👍 Keep practicing circuit problems — every solved example is a step closer to acing NEET!