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A YDSE is performed in a medium of refra...

A YDSE is performed in a medium of refractive index `4 // 3`, A light of 600 nm wavelength is falling on the slits having 0.45 nm separation . The lower slit `S_(2)` is covered b a thin glass plate of thickness 10.4 mm and refractive index 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in figure. (All the wavelengths in this problem are for the given medium of refractive index `4 // 3`, ignore absorption.)

The location of the central maximum (bright fringe with zero path difference) on the y-axis will be

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A YDSE is performed in a medium of refractive index 4 // 3 , A light of 600 nm wavelength is falling on the slits having 0.45 nm separation . The lower slit S_(2) is covered b a thin glass plate of thickness 10.4 mm and refractive index 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in figure. (All the wavelengths in this problem are for the given medium of refractive index 4 // 3 , ignore absorption.) Find the light intensity at point O relative t maximum fringe intensity.

A YDSE is performed in a medium of refractive index 4 // 3 , A light of 600 nm wavelength is falling on the slits having 0.45 nm separation . The lower slit S_(2) is covered b a thin glass plate of thickness 10.4 mm and refractive index 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in figure. (All the wavelengths in this problem are for the given medium of refractive index 4 // 3 , ignore absorption.) Find the light intensity at point O relative t maximum fringe intensity.

A YDSE is performed in a medium of refractive index 4 // 3 , A light of 600 nm wavelength is falling on the slits having 0.45 nm separation . The lower slit S_(2) is covered b a thin glass plate of thickness 10.4 mm and refractive index 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in figure. (All the wavelengths in this problem are for the given medium of refractive index 4 // 3 , ignore absorption.) Now, if 600 nm, find the wavelength of the ligth that forms maximum exactly at point O.

A YDSE is performed in a medium of refractive index 4 // 3 , A light of 600 nm wavelength is falling on the slits having 0.45 nm separation . The lower slit S_(2) is covered b a thin glass plate of thickness 10.4 mm and refractive index 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in figure. (All the wavelengths in this problem are for the given medium of refractive index 4 // 3 , ignore absorption.) Now, if 600 nm, find the wavelength of the ligth that forms maximum exactly at point O.

The Young's double-slit experiment is done in a medium of refractive index 4//3. A light of 600 nm wavelength is falling on the slits having 0.45 mm separation. The lower shift S_(2) is covered by a thin glass sheet of thickness 10.4 mm and refractive index. 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in Figure Find the light intensity of point O relative to the maximum fringe intensity.

The Young's double-slit experiment is done in a medium of refractive index 4//3. A light of 600 nm wavelength is falling on the slits having 0.45 mm separation. The lower shift S_(2) is covered by a thin glass sheet of refractive index. 1.5. The interference pattern is observed on a screen placed 1.5 m from the slits as shown in Figure a. Find the location of central maximum (bright fringe with zero path difference) on the y-axis.

In YDSE's experiment performed in a medium of refractive index (4/3), a light of 60 nm wavelength is falling ono the slits having 0.45 mm separation.t he lower slit S_(2) is covered by a thin glass sheet of thickness 10.4 mum and refractive index 1.5 the interference pattern is observed on a screen palced 1.5m from the slits as shown int hef ignore dispersion. Q. If white light of range 400-700 nm has replaced 600 nm light, one of the wavelengths of light that forms maxima exactly at point O wll be: