Two ideal slits `S_(1)` and `S_(2)` are at a distance d aprt and illuminated by light of wavelength `lambda` passing through an ideal source slit S placed on the line throught `S_(2)` as shown. The distance between the planes of slits and the source slit of D. A screen is held at a distance D from the plane of the slits. The minimum value of d for which there is darkness at O is

Two ideal slits S_(1) and S_(2) are at a distance d apart, and illuninated by light of wavelength lambda passing through an ideal source slit S placed on the line through S_(2) as shown. The distance between the planes of slits and the source slit is D.A screen is held at a distance D from the plane of the slits. The minimum value of d for which there is darkness at O is (dlt lt D)

A parallel beam of light of wavelength lambda passes through a slit of width d. The transmitted light is collected on a screen D aways (D gt gt d) . Find the distance between the two second order minima.

In a double slit experiment, the distance between the slits is d. The screen is at a distance D from the slits. If a bright fringe is formed opposite to one of the slits, its order is

In a single slit diffraction method, the distance between slit and screen is 1m . The size of the slit is 0.7mm and second maximum is formed at the distance of 2mm from the centre of the screen, then find out the wavelength of light.

White light of wavelength in range 400 nm to 700 nm is incident normaly on a young's double slit experiment apparatus. The distance betweenn slits is d=1 mm and distance between plane of the slits and screen in 0.8 m. At a point on the screen just in front of one of the slits the missing wavelength is (are)

Two slits are separated by a distance of 0.5mm and illuminated with light of lambda=6000Å . If the screen is placed 2.5m from the slits. The distance of the third bright image from the centre will be

In a single slit diffraction of light of wavelength lambda by a slit of width e, the size of the central maximum on a screen at a distance b is

Consider the situation shown in figure. The two slits S_1 and S_2 placed symmetrically around the central line are illuminated by a monochromatic light of wavelength lamda . The separation between the slits is d. The light transmitted by the slits falls on a screen Sigma_1 placed at a distance D from the slits. The slit S_3 is at the placed central line and the slit S_4 , is at a distance z from S_3 . Another screen Sigma_2 is placed a further distance D away from 1,1. Find the ratio of the maximum to minimum intensity observed on Sigma_2 if z is equal to a. z=(lamdaD)/(2d) b. (lamdaD)/d c. (lamdaD)/(4d)

Consider the situation shown in figure. The two slite S_1 and S_2 placed symmetrically around the centre line are illuminated by a monochromatic light of wavelength lambda. The separation between the slits is d. The light transmitted by the slits falls on a screen M_1 placed at a distance D from the slits. The slit S_3 is at the centre line and the slit S_4 is at a distance y form S_3 . Another screen M_2 is placed at a further distance D away from M_1 . Find the ration of the maximum to minimum intensity observed on M_2 if y is equal to (dltltD) .

Consider two slit interference arrangements as shown in figure . The distance of screen from the slits is half the distance between the slits. Then the value of 'D' if fisrt minima on screen falls at a distance D from the centre 'C' ( lambda is the wavelength of the source).