According to Ohm's Law, the resistance of a wire is directly influenced by its length and inversely influenced by its cross-sectional area. Ohm's Law is represented by the formula:
R = ฯ * (L / A)
Where:
R is the resistance of the wire (measured in ohms, ฮฉ).
ฯ (rho) is the electrical resistivity of the material the wire is made of (measured in ohm-meters, ฮฉยทm).
L is the length of the wire (measured in meters, m).
A is the cross-sectional area of the wire (measured in square meters, mยฒ).
Length (L):
The resistance of a wire increases with its length. This is because, with a longer wire, there is a greater distance for the electric current to travel, leading to more collisions between electrons and the atoms of the wire material. These collisions impede the flow of current, resulting in higher resistance.
Mathematically, as you can see in the formula, resistance is directly proportional to the length of the wire (R โ L). So, if you double the length of the wire while keeping other factors constant, the resistance will also double.
Cross-sectional area (A):
The resistance of a wire decreases with an increase in its cross-sectional area. This is because a larger cross-sectional area provides more space for electrons to flow through, reducing the chances of collisions with the wire's atoms. As a result, the current can pass more easily through a wire with a larger cross-sectional area.
Mathematically, resistance is inversely proportional to the cross-sectional area (R โ 1/A). If you double the cross-sectional area of the wire while keeping other factors constant, the resistance will be halved.
In summary, longer wires have higher resistance, and wires with larger cross-sectional areas have lower resistance. These relationships are essential to understand when designing electrical circuits or choosing wires for specific applications to ensure the desired flow of current and minimize energy losses due to resistance.