The dimension of $ \sqrt{\frac{\mu_0}{\epsilon_0}} $ is equal to that of: (Where $ \mu_0 $ is the vacuum permeability and $ \epsilon_0 $ is the vacuum permittivity)
The dimension of $ \sqrt{\frac{\mu_0}{\epsilon_0}} $ is equal to that of: (Where $ \mu_0 $ is the vacuum permeability and $ \epsilon_0 $ is the vacuum permittivity)
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- Voltage
- Capacitance
- Inductance
- Resistance
The Correct Option is C
Approach Solution - 1
To solve the problem, we need to determine the dimensions of the expression \(\sqrt{\frac{\mu_0}{\epsilon_0}}\), where \(\mu_0\) is the vacuum permeability and \(\epsilon_0\) is the vacuum permittivity.
We know that:
- The dimension of permeability \(\mu_0\) is [M L T^{-2} A^{-2}].
- The dimension of permittivity \(\epsilon_0\) is [M^{-1} L^{-3} T^4 A^2].
Thus, the expression can be evaluated as follows:
\(\frac{\mu_0}{\epsilon_0} = \frac{[M L T^{-2} A^{-2}]}{[M^{-1} L^{-3} T^4 A^2]} = [M^{1+1} L^{1+3} T^{-2-4} A^{-2-2}]\)
Simplifying, we get:
[M^2 L^4 T^{-6} A^{-4}]
Taking the square root of this expression gives:
\(\sqrt{[M^2 L^4 T^{-6} A^{-4}]} = [M^{1} L^{2} T^{-3} A^{-2}]\)
The dimension [M^{1} L^{2} T^{-3} A^{-2}] corresponds to that of inductance. Therefore, the correct answer is Inductance.
Approach Solution -2
The vacuum permeability \( \mu_0 \) and the vacuum permittivity \( \epsilon_0 \) have the following dimensional formulas: \[ [\mu_0] = \text{M}^{-1} \text{L} \text{T}^{-2} \text{A}^2, \quad [\epsilon_0] = \text{M}^{-1} \text{L}^{-3} \text{T}^4 \text{A}^2. \]
Step 2: Calculate the dimension of \( \sqrt{\frac{\mu_0}{\epsilon_0}} \).
Now, substitute the dimensions of \( \mu_0 \) and \( \epsilon_0 \) into the expression \( \sqrt{\frac{\mu_0}{\epsilon_0}} \): \[ \left[\sqrt{\frac{\mu_0}{\epsilon_0}}\right] = \sqrt{\frac{\text{M}^{-1} \text{L} \text{T}^{-2} \text{A}^2}{\text{M}^{-1} \text{L}^{-3} \text{T}^4 \text{A}^2}}. \]
Step 3: Simplify the dimensional formula.
Simplifying the above expression: \[ \left[\sqrt{\frac{\mu_0}{\epsilon_0}}\right] = \sqrt{\text{M}^0 \text{L}^4 \text{T}^{-6} \text{A}^0} = \text{L}^2 \text{T}^{-2}. \]
Step 4: Identify the physical quantity.
The dimension \( \text{L}^2 \text{T}^{-2} \) corresponds to the dimension of inductance.
Thus, the dimension of \( \sqrt{\frac{\mu_0}{\epsilon_0}} \) is equal to that of inductance.
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