Two wavelengths of light `lambda_(1)` and `lambda_(2)` are sent through Young's double-slit apparatus simultaneously. If the third-order bright fringe coincides with the fourth-order bright fringe, then

Two wavelengths of light lambda_(1) and lambda_(2) and sent through Young's double-slit apparatus simultaneously. If the third-order bright fringe coincides with the fourth-order bright fringe, then

Two wavelengths of light lambda_1 and lambda_2 are sent through Young's double slit experiment simultaneously. If the third order bright fringe of lambda_1 coincides with fifth order dark fringe of lambda_2 , then

Two wavelength of light lambda_(1) and lambda_(2) are sent through Young's double-slit apparatus simultaneously. What must be true about lambda_(1) and lambda_(2) if the third-order bright fringe of lambda_(1) coincides with fifth-order dark fringe of lambda_(2)

Lights of wavelengths lambda_(1)=4500 Å, lambda_(2)=6000 Å are sent through a double slit arrangement simultaneously. Then

In a Young's double-slit experiment, the central bright fringe can be identified

A source emitting light of wavelengths lambda_1 and lambda_2 is used in Young's double-slit experiment. If fourth bright of lambda_1 coincides with sixth bright of lambda_2 , then

In Young's double slit experiment, if the width of 4th bright firnge is 2xx10^(-2) cm then the width of 6 th bright fringe will be cm

In Young's double slit experiment, the interference bright fringes are of:

In Young's double slit experiment the phase difference between the waves reaching the central fringe and fourth bright fringe will be

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