In a single slit diffraction experiment first minima for `lambda_1 = 660nm` coincides with first maxima for wavelength `lambda_2`. Calculate the value of `lambda_2`.

In an experiment of single slit diffraction pattern first minimum for red light coincides with first maximum of some other wavelength. If wavelength of red light is 6600 A^(0) , then wavelength of first maximum will be :

Width of slit in a single slit diffraction experiment such that 20 maxima of double slit interference pattern are obtained within central maxima of the diffraction pattern is ( Slit separation for double slit arrangement =2mm)

In YDSE pattern with light of wavelength lambda_1 = 500nm , 15 fringes are obtained on a certain segment of screen. If number of fringes for light of wavelength lambda_2 on same segment of screen is 10, then the value of lambda_2 (in nm) is-

In YDSE pattern with light of wavelength lambda_1 = 500nm , 15 fringes are obtained on a certain segment of screen. If number of fringes for light of wavelength lambda_2 on same segment of screen is 10, then the value of lambda_2 (in nm) is-

A beam of light consisting of two wavelength 6300 A^(@) and lambda A^(@) is used to obtain interference frings in a Young's double slit experiment. If 4^(th) bright fringe of 6300 A^(@) coincides with 5^(th) dark fringe of lambdaA^(@) , the value of lambda (in A^(@) ) is

In a single slit diffraction set up, second minima is observed at an angle of 60^(@) . The expected position of first minima is

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

if mu_21 is 1.5, then find the value of lambda_1/lambda_2.

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

A lens of focal length 1m forms Fraunhofer diffraction pattern of a single slit of width 0.04 cm in its focal plane. The incident light contains two wavelength lambda_(1) and lambda_(2) . It is found that the fourth minimum corresponding to lambda_(1) and the fifth minimum corresponding to lambda_(2) occur at the same point 0.5 cm from the central maximum. Compute lambda_(1) and lambda_(2)