Question:
In case of diffraction, if \( a \) is a slit width and \( \lambda \) is the wavelength of the incident light, then the required condition for diffraction to take place is:
In case of diffraction, if \( a \) is a slit width and \( \lambda \) is the wavelength of the incident light, then the required condition for diffraction to take place is:
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Diffraction is significant when the slit width is comparable to or smaller than the wavelength of light.
Updated On: Mar 18, 2026
- \( \frac{a}{\lambda} = 1000 \)
- \( \frac{a}{\lambda} \leq 1 \)
- \( a \ll \lambda \)
- \( a \gg \lambda \)
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The Correct Option is B
Solution and Explanation
Step 1: Understanding Diffraction Condition
For diffraction to occur, the slit width \( a \) must be of the same order of magnitude as the wavelength \( \lambda \), i.e.:
\[
\frac{a}{\lambda} \leq 1
\]
Step 2: Explanation
- If \( a \gg \lambda \), no noticeable diffraction occurs.
- If \( a \ll \lambda \), diffraction effects are maximized.
- The practical condition is \( \frac{a}{\lambda} \leq 1 \).
- If \( a \ll \lambda \), diffraction effects are maximized.
- The practical condition is \( \frac{a}{\lambda} \leq 1 \).
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