The figure shows a double slit experiment P and Q are the slits. The path lengths PX and QX are `n lamda` and `(n + 2)lamda` respectively. Where n is a whole number and `lamda` is the wavelength. Taking the central fringe as zero. What is formed at X

The figure shows a double slit experiment with P and Q as the slits. The path lengths PX and QX are nlambda and (n+2)lambda respectively, where n is a whole number and lambda is the wavelength. Taking the central fringe as zero, what is formed at X?

In a Young's double slit experiment using red and blue lights of wavelengths 600 nm and 480 nm respectively, the value of n for which the nth red fringe coincides with (n+1) th blue fringe is

The figure shows a Young's double slit experimental setup. It is observed that when a thin transparent sheet of thickness t and refractive index mu is put front of one of the slits, the central maximum gets shifted by a distance equal to n fringe widths. If the wavelength of light used is lambda , t will be :

In Young's double slit experiment, wavelength lambda=5000Å the distance between, the slits is 0.2mm and the screen is at 200cm from the slits. The central maximum is at x=0 The third maximum (Taking the central maximum as zeroth maximum) will be at x equal to

A plate of thickness t made of a material of refractive index mu is placed in front of one of the slits in a double slit experiment. (a) Find the changes in the optical path due to introduction of the plate. (b) What should be the minimum thickness t which will make the intensity at the center of the fringe pattern zero ? Wavelength of the light used is lamda . Neglect any absorption of light in the plate.

A plate of thickness t made of a material of refractive index mu is placed in front of one of the slits in a double slit experiment. (a) Find the changes in he optical path due to introduction of the plate. (b) Wht should be the minimum thickness t which will make the intensity at the centre of the fringe pattern zero ? Wavelength of the light used is lamda . Neglect any absorption of light in the plate.

In the figure is shown Young's double slit experiment. Q is the position of the first bright fringe on the right side of O. P is the 11^(th) bright fringe on the other side, as measured from Q. If the wavelength of the light used is 600 nm . Then S_(1)B will be equal to

The figure shows the interfernece pattern obtained in double slit experiment using light of wavelength 600 nm. Q. The third order bright fringe is

In young's double-slit experiment, the slit are 2 mm apart and are illuminated with a mixture ot two wavelengths lambda_(0) = 750 nm and lambda = 900 nm , The minimum distance from the common central bright fringe on a screen 2 m from the slits, where a bright fringe from one interference pattern coincides with a bright fringe from the other, is

In the Young's double slit experiment using a monochromatic light of wavelength lamda , the path difference (in terms of an integer n) corresponding to any point having half the peak