The angle of diffraction `2 theta` for a first `-` order nature was found to be `27^(@)8'` using `X-` rays of wavelength `2.29Å`. Calculate the distance between two diffracted planes.

A slit of aperture 1.8 mm is illuminated by light of wavelength 5,000 Å . Calculate the minimum distance light can travel before the diffraction is noticed.

The angle of reflection for first order monochromatic X-rays from a crystal whose atomic spacing is 2.5 Å is 15^(@) . Calculate the wavelength of X-rays.

The second order Bragg diffraction of X rays with lambda=Å form a set of parallel planes in a metal occurs at an angle 60^(@) . the distance between the scattering planes in the crystal is

The distance between the first and fifth minima of a single slit diffraction patterns is 0.40 mm with screen 50 cm away from the slit, using light of wavelength 550 . (a) Find the slit width (b) Calculate the angle of the first diffraction minimum

The width of central fringe of a diffraction pattern is 5.8 mm on a screen at a distance 2m. If light source has wavelength 5800 Å then the slit width

In Fraunhofer diffraction pattern, slit width is 0.2 mm and screen is at 2 m away from the lens. If wavelength of light used is 5000 Å , then the distance between the first minimum on either side of the central maximum is ( theta is small and measured in radian)

The first minimum of a single slit diffraction pattern is observed at angle 2^(@) with a light of wavelength 698 nm. The width of this slit is

For a cyrstal, the angle of diffraction (2 theta) is 90(@) and the second order line has a d value of 2.28Å. The wavelength (inÅ) of X-rays used for Bragg's diffraction is

Calculate the angle at which first order reflection will occur in an X-ray spectrometer when X-rays of wavelength 1.54Å are diffracted by the atoms of a crystal given that interplanar distance is 0.04Å .