White coherent light `(400 nm-700 nm)` is sent through the slits of a YDSE. `d=0.5 mm`, D=50 cm. There is a hole in the screen at a point `1.0 mm` away (along the width of the fringes) from the central line.
(a) Which wavelength will be absent in the light coming from the hole?
(b) Which wavelength(s) will have a strong intensity?

White coheral light (400 nm 700 nm ) is sent through the slit of a Young.s double slit experiment. The separation between the slits is 0.5 mm and the screen is 50 away from the slits . There is a hole in the screen at a point 1.0 mm away (along the width of the fringes) from the central line. Which wavelengths (s) will be absent in the light coming from the hole ?

White coherent light (400 nm- 700 nm) is sent through the slits of a young.s double slit experiment. The separation between the slits is 0.5 mm and the screen is 50 cm away from the slits. There is a hole in the screen at a point 1 mm from the centre. In the above problem which wavelength have a strong intensity at the hole?

In this problem , which wavelength (s) will have a strong intensity if light have wavelength 400 nm-700 nm?

In young's double slit experiment shown in figure, S_1 and S_2 are coherent sources and S in the screen having a hole at a point 1.0 mm away from the central line. White light (400 to 700 nm) is sent through the slits. Which wavelength passing through the hole has strong intensity?

A double slit of separation 1.5 mm is illuminated by white light (between 4000 and 8000 Å ). On a screen 120 cm away colored interference pattern is formed. If a pinhole is made on this screen at a distance of 3.0 mm from the central white fringe, some wavelengths will be absent in the transimitted light. Find the second longest wavelength (in Å ) which will be absent in the transmitted light.

With two slits spaced 0.2 mm apart and a screen at a distance of 1 m, the third bright fringe is found to be at 7.5 mm from the central fringe. The wavelength of light used is

Light of wavelength 580 nm is incident on a slit having a width of 0.300 nm The viewing screen is 2.00 m from the slit. Find the positions of the first dark fringe and the width of the central bright fringe.

Light from a sodium lamp. lambda . = 600 nm, is diffracted by a slit of width d= 0.60 mm. The distance from the slit to the screen is D = 0.60 m. Then, the width of the central maximum is

In YDSE, separation between slits is 0.15 mm, distance between slits and screen is 1.5 m and wavelength of light is 589 nm, then fringe width is

In YDSE, separation between slits is 0.15 mm, distance between slits and screen is 1.5 m and wavelength of light is 589 nm, then fringe width is