In Young's double slit experiment, the wavelength of red light is `7800 Å`. The value of n for which nth bright band due to red light coincides with `(n+1)th` bright band due to blue light`(lambda=5200Angstrom)`, is

In Young's experiment the wavelenght of red light is 7.8xx10^(-5) cm and that of blue light is 5.2xx10^(-5) cm. The value of n for which (n+1)^(th) blue bright band coincides with n^(th) red band is

In Young's double slit experiment, two wavelength lamda_(1)=780nm and lamda_(2)=520 nm are used to obtain interference fringes. If the nth bright band due to lamda_(1) coincides with (n+1)^(th) bright band due to lamda_(2) then the value of n is

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

In Young.s double slit experiment, what is the path difference between the two light waves forming 5th bright band (fringe) on the screen ?

A : In Young.s double slit expriment the band width for red colour is more R : Wavelength of red is small among the colours of white light.

In a Young's double slit experiment, the source is white light. One of the holes is covered by a red filter and another by a blue filter. In this case

In a Young's double slit experiment, the source is white light. One of the holes is covered by a red filter and another by a blue filter. In this case

In Young's double slit experiment, if the distance between two slits is equal to the wavelength of used light. Then the maximum number of bright firnges obtained on the screen will be

In young's double slit experiment the n^(th) red bright band coincides with (n+1)^(th) blue bright band. If the wavelength of red and blue lights are 7500 A^(@) and 5000 A^(@) , the value of 'n' is

In Young's double-slit experiment, the ratio of intensities of a bright band and a dark band is 16:1 . The ratio of amplitudes of interfering waves will be