368024
In Young’s double slit experiment, a maxima is obtained when the phase difference of super imposing waves is (\(n\) is a positive integer)
1 \(n\pi \)
2 \(\left( {2n - 1} \right)\pi \)
3 \(\left( {n + 1} \right)\pi \)
4 Zero
Explanation:
Conceptual Question
PHXII10:WAVE OPTICS
368025
In young's double slit experiment, the phase difference between the light waves reaching a point where third bright fringe forms will be \(\left( {\lambda = 6000\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\)
1 Zero
2 \(2 \pi\)
3 \(4 \pi\)
4 \(6 \pi\)
Explanation:
The phase difference between the light waves reaching the third bright fringe from the central bright fringe will be \(\Delta \phi=2 n \pi ; n=3\). \(\Delta \phi=2 \times 3 \times \pi=6 \pi\) (case of constructive interference)
PHXII10:WAVE OPTICS
368026
In Young’s double slit experiment, the intensity of the maxima is \(I\). If the width of each slit is doubled, the intensity of the maxima will be
NEET Test Series from KOTA - 10 Papers In MS WORD
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PHXII10:WAVE OPTICS
368024
In Young’s double slit experiment, a maxima is obtained when the phase difference of super imposing waves is (\(n\) is a positive integer)
1 \(n\pi \)
2 \(\left( {2n - 1} \right)\pi \)
3 \(\left( {n + 1} \right)\pi \)
4 Zero
Explanation:
Conceptual Question
PHXII10:WAVE OPTICS
368025
In young's double slit experiment, the phase difference between the light waves reaching a point where third bright fringe forms will be \(\left( {\lambda = 6000\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\)
1 Zero
2 \(2 \pi\)
3 \(4 \pi\)
4 \(6 \pi\)
Explanation:
The phase difference between the light waves reaching the third bright fringe from the central bright fringe will be \(\Delta \phi=2 n \pi ; n=3\). \(\Delta \phi=2 \times 3 \times \pi=6 \pi\) (case of constructive interference)
PHXII10:WAVE OPTICS
368026
In Young’s double slit experiment, the intensity of the maxima is \(I\). If the width of each slit is doubled, the intensity of the maxima will be
368024
In Young’s double slit experiment, a maxima is obtained when the phase difference of super imposing waves is (\(n\) is a positive integer)
1 \(n\pi \)
2 \(\left( {2n - 1} \right)\pi \)
3 \(\left( {n + 1} \right)\pi \)
4 Zero
Explanation:
Conceptual Question
PHXII10:WAVE OPTICS
368025
In young's double slit experiment, the phase difference between the light waves reaching a point where third bright fringe forms will be \(\left( {\lambda = 6000\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\)
1 Zero
2 \(2 \pi\)
3 \(4 \pi\)
4 \(6 \pi\)
Explanation:
The phase difference between the light waves reaching the third bright fringe from the central bright fringe will be \(\Delta \phi=2 n \pi ; n=3\). \(\Delta \phi=2 \times 3 \times \pi=6 \pi\) (case of constructive interference)
PHXII10:WAVE OPTICS
368026
In Young’s double slit experiment, the intensity of the maxima is \(I\). If the width of each slit is doubled, the intensity of the maxima will be
368024
In Young’s double slit experiment, a maxima is obtained when the phase difference of super imposing waves is (\(n\) is a positive integer)
1 \(n\pi \)
2 \(\left( {2n - 1} \right)\pi \)
3 \(\left( {n + 1} \right)\pi \)
4 Zero
Explanation:
Conceptual Question
PHXII10:WAVE OPTICS
368025
In young's double slit experiment, the phase difference between the light waves reaching a point where third bright fringe forms will be \(\left( {\lambda = 6000\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\)
1 Zero
2 \(2 \pi\)
3 \(4 \pi\)
4 \(6 \pi\)
Explanation:
The phase difference between the light waves reaching the third bright fringe from the central bright fringe will be \(\Delta \phi=2 n \pi ; n=3\). \(\Delta \phi=2 \times 3 \times \pi=6 \pi\) (case of constructive interference)
PHXII10:WAVE OPTICS
368026
In Young’s double slit experiment, the intensity of the maxima is \(I\). If the width of each slit is doubled, the intensity of the maxima will be
