What happens to the resistance of the wire when its length is increased to twice its original length?
1 Answer
This gets to the core of how resistance works.
The short and direct answer is:
The resistance of the wire will double.
Here's a more detailed explanation of why.
1. The Simple Explanation (Analogy)
Think of the wire as a narrow hallway and the electric current as people trying to get through it.
- Resistance is the difficulty the people have moving through the hallway (bumping into walls, other people, etc.).
- If you make the hallway twice as long, the people have to travel twice the distance and will face twice the overall difficulty.
Similarly, when electrons travel through a longer wire, they encounter more atoms to bump into along their path, which increases the total opposition (resistance) to their flow.
2. The Physics Explanation (The Formula)
The resistance ($R$) of a wire is determined by the following formula:
$R = \rho \frac{L}{A}$
Where:
$R$ = Resistance (in Ohms, Ω)
$\rho$ (rho) = Resistivity. This is a property of the material itself (e.g., copper has very low resistivity, while rubber has very high resistivity).
$L$ = Length of the wire.
$A$ = Cross-sectional area of the wire (how thick it is).
From this formula, you can see that resistance ($R$) is directly proportional to the length ($L$). If the resistivity ($\rho$) and area ($A$) stay the same, whatever you do to the length will happen to the resistance.
Let's do the math:
- Original Resistance: $R_{original} = \rho \frac{L}{A}$
- New Length: $L_{new} = 2 \times L$
- New Resistance: $R{new} = \rho \frac{L{new}}{A} = \rho \frac{2L}{A}$
If you compare the two, you can see that:
$R{new} = 2 \times \left( \rho \frac{L}{A} \right) = 2 \times R{original}$
So, doubling the length doubles the resistance.
An Important Distinction: Stretching the Wire
There is a common "trick" version of this question in physics problems:
Question: What happens to the resistance if a wire is stretched to twice its original length?
Answer: The resistance will quadruple (increase by 4 times).
Why? When you stretch a wire, its volume must stay the same. To make it twice as long, it must also get thinner.
- Length Doubles: $L_{new} = 2L$
- Area Halves: To keep the volume constant (Volume = Length × Area), the cross-sectional area must become half of what it was. $A_{new} = A/2$
Now, let's put these new values into the resistance formula:
$R{new} = \rho \frac{L{new}}{A{new}} = \rho \frac{2L}{A/2} = \rho \frac{4L}{A} = 4 \times \left( \rho \frac{L}{A} \right) = 4 \times R{original}$
Summary
| Scenario | Change in Length | Change in Area | Change in Resistance |
| -------------------------------------------- | --------------------- | ----------------- | -------------------------- |
| Adding length (e.g., connecting a second identical wire) | Doubles (x2) | Stays the same | Doubles (x2) |
| Stretching the original wire | Doubles (x2) | Halves (x0.5) | Quadruples (x4) |