Qstnid -Iv-21-a Narrow Slit S Transmitting Light Of Wavelength Λis Placed A Distance D Above A Large Plane Mirror, As Shown In The Figure (17-e1). The Light Coming Directly From The Slit And That Coming After The Reflection Interfere At A Screen ∑ Placed At A Distance D From The Slit. (A) What Will Be The Intensity At A Point Just Above The Mirror, I.e. Just Above O? (B) At What Distance From O Does The First Maximum Occur? <Span Style="background-color: #Ffff00;">figure</span></span> - 17: Light Waves - Neet-xii-physics

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NEET-XII-Physics

17: Light Waves

with Solutions - page 6

Qstn# iv-21 Prvs-Qstn Next-Qstn

#21
A narrow slit S transmitting light of wavelength
λis placed a distance d above a large plane mirror, as shown in the figure (17-E1). The light coming directly from the slit and that coming after the reflection interfere at a screen ∑ placed at a distance D from the slit. (a) What will be the intensity at a point just above the mirror, i.e. just above O? (b) At what distance from O does the first maximum occur?
Figure
Ans : (a) The phase of a light wave reflecting from a surface differs by '`` \pi ``' from the light directly coming from the source.

Thus, the wave fronts reaching just above the mirror directly from the source and after reflecting from the mirror have a phase difference of `` \pi ``, which is the condition of distractive interference. So, the intensity at a point just above the mirror is zero. (b) Here, separation between two slits is `` 2d``.
Wavelength of the light is `` \lambda ``.
Distance of the screen from the slit is `` D``.
Consider that the bright fringe is formed at position y. Then,
path difference, `` ∆x=\frac{y\times 2d}{D}=n\lambda ``.
After reflection from the mirror, path difference between two waves is `` \frac{\lambda }{2}``.
`` \Rightarrow \frac{y\times 2d}{D}=\frac{\lambda }{2}+n\lambda ``
`` \,\mathrm{\,For\,}\,\mathrm{\,first\,}or\,\mathrm{\,der\,},\,\mathrm{\,put\,}n=0.``
`` \Rightarrow y=\frac{\lambda D}{4d}``
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#21-a
What will be the intensity at a point just above the mirror, i.e. just above O?
Ans : The phase of a light wave reflecting from a surface differs by '`` \pi ``' from the light directly coming from the source.

Thus, the wave fronts reaching just above the mirror directly from the source and after reflecting from the mirror have a phase difference of `` \pi ``, which is the condition of distractive interference. So, the intensity at a point just above the mirror is zero.

#21-b
At what distance from O does the first maximum occur?
Figure
Ans : Here, separation between two slits is `` 2d``.
Wavelength of the light is `` \lambda ``.
Distance of the screen from the slit is `` D``.
Consider that the bright fringe is formed at position y. Then,
path difference, `` ∆x=\frac{y\times 2d}{D}=n\lambda ``.
After reflection from the mirror, path difference between two waves is `` \frac{\lambda }{2}``.
`` \Rightarrow \frac{y\times 2d}{D}=\frac{\lambda }{2}+n\lambda ``
`` \,\mathrm{\,For\,}\,\mathrm{\,first\,}or\,\mathrm{\,der\,},\,\mathrm{\,put\,}n=0.``
`` \Rightarrow y=\frac{\lambda D}{4d}``
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