Question:medium

If in a free space, the electric field is given as: \[ \vec{E} = 20 \cos(\omega t - 50x) \hat{y} \, \text{V/m} \] then, the expression of displacement current density \( J_d \) is:

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Displacement current density is related to the time rate of change of the electric field in free space.
Updated On: Feb 18, 2026
  • \( -20 \omega \epsilon_0 \cos(\omega t - 50x) \hat{y} \, \text{A/m}^2 \)
  • \( -20 \omega \epsilon_0 \sin(\omega t - 50x) \hat{y} \, \text{A/m}^2 \)
  • \( -10 \omega \epsilon_0 \sin(\omega t - 50x) \hat{y} \, \text{A/m}^2 \)
  • \( -20 \omega \sin(\omega t - 50x) \hat{y} \, \text{A/m}^2 \)
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The Correct Option is B

Solution and Explanation

Step 1: Displacement Current Explained.
The displacement current density is defined as: \[J_d = \epsilon_0 \frac{\partial \vec{E}}{\partial t}\]Given the electric field \( \vec{E} = 20 \cos(\omega t - 50x) \hat{y} \), its time derivative is: \[\frac{\partial \vec{E}}{\partial t} = -20 \omega \sin(\omega t - 50x) \hat{y}\]Therefore, the displacement current density becomes: \[J_d = -20 \omega \epsilon_0 \sin(\omega t - 50x) \hat{y}\]
Step 2: Final Answer.
Option (2) provides the correct expression for the displacement current density.
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