Class 10 Science Electricity Notes

Class 10 Science Electricity Notes

Introduction

Electricity is the flow of electric charge (usually electrons) through a conductor.
It powers many devices and is essential in everyday life.

1. Electric Current

Definition: The flow of electric charge through a conductor.
SI unit of current: Ampere (A)
Formula:
I=QtI = \frac{Q}{t}I=tQ
Where:
- $I$ I = Current (in amperes, A)
- $Q$ Q = Charge (in coulombs, C)
- $t$ t = Time (in seconds, s)

Direction of Current

Conventional Current: Flows from positive to negative (opposite to electron flow).

2. Potential Difference (Voltage)

Definition: The difference in electric potential energy between two points in a circuit.
SI unit of voltage: Volt (V)
Formula:
V=WQV = \frac{W}{Q}V=QW
Where:
- $V$ V = Voltage (in volts, V)
- $W$ W = Work done (in joules, J)
- $Q$ Q = Charge (in coulombs, C)
Potential Difference causes the flow of current in a circuit.

3. Ohm’s Law

Statement: The current flowing through a conductor is directly proportional to the potential difference across it and inversely proportional to its resistance.
Formula:
V=I×RV = I \times RV=I×R
Where:
- $V$ V = Voltage (in volts, V)
- $I$ I = Current (in amperes, A)
- $R$ R = Resistance (in ohms, Ω)
Resistance: The opposition to the flow of current.
SI unit of resistance: Ohm (Ω)

Factors Affecting Resistance

Material: Conductors have low resistance (e.g., copper), while insulators have high resistance.
Length: Longer conductors have higher resistance.
Area of Cross-Section: Wider conductors have lower resistance.
Temperature: Higher temperature increases resistance.

4. Resistance in Series and Parallel Circuits

Series Circuit

Current is the same through all components.
Total resistance: $R_{total} = R_1 + R_2 + \dots$ Rtotal=R1+R2+…
Total Voltage: $V_{total} = V_1 + V_2 + \dots$ Vtotal=V1+V2+…

Parallel Circuit

Voltage is the same across all components.
Total resistance:
$\frac{1}{R_{total}} = \frac{1}{R_1} + \frac{1}{R_2} + \dots$ Rtotal1=R11+R21+…
Total Current: $I_{total} = I_1 + I_2 + \dots$ Itotal=I1+I2+…

5. Electric Power

Definition: The rate at which electrical energy is consumed or converted into other forms of energy.
Formula:
P=V×IP = V \times IP=V×I
Where:
- $P$ P = Power (in watts, W)
- $V$ V = Voltage (in volts, V)
- $I$ I = Current (in amperes, A)
Unit of power: Watt (W)
1 kW = 1000 W
Energy consumed (in kilowatt-hours):
E=P×tE = P \times tE=P×t
Where:
- $E$ E = Energy (in kWh)
- $P$ P = Power (in kW)
- $t$ t = Time (in hours)

6. Heating Effect of Electric Current

When current flows through a conductor, it produces heat.
Joule’s Law:
H=I2×R×tH = I^2 \times R \times tH=I2×R×t
Where:
- $H$ H = Heat produced (in joules)
- $I$ I = Current (in amperes, A)
- $R$ R = Resistance (in ohms, Ω)
- $t$ t = Time (in seconds, s)
Applications of heating effect: Electric heaters, fuses, and electric bulbs.