Visible light of wavelength 6000 ` xx 10 ^( - 8 ) ` cm falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at ` 60 ^(@) ` from the central maximum. If the first minimum is produced at ` theta _ 1`, then ` theta _ 1 ` is close to :

Visible light of wavelenght 8000 xx 10^(-8) cm falls normally on a single slit and produces a diffraction pattern. It is found that the Third diffraction minimum is at 45^(@) from the central maximum. If the first minimum is produced at theta_(1) then theta_(1) is close to :

Visible light of wavelength 500 nm falls normally on a single slit and produces a diffraction pattern. It is found that the diffraction pattern is on a screen 1 m away from slit. If the first minimum is produced at a distance of 2.5 mm from the centre of screen, then the width of the slit is

In a single slit diffraction pattern

In single slit diffraction pattern :

A bichromatic light having wavelength gamma_1 and gamma_2 falls normally on a single slit and produces a diffraction pattern. It is found that the first diffraction minimum for gamma_1 is at 30^(@) and second diffraction minimum for gamma_2 is at 45^(@) from the central maximum. If gamma_1 is 5000xx10^(-8) cm, then the value of gamma_2 is close to:

In a single slit diffraction pattern intensity and width of fringes are

No fringes are seen in a single-slit diffraction pattern if

Light of wavelength 600 nm is incident normally on a slit of width 0.2 mm. The angular width of central maxima in the diffraction pattern is

The fringe width in single slit diffraction pattern is proportional to