In a double-slit pattern `(lambda=6000Å)`, the zero-order and tenth-order maxima fall at 12.34 mm and 1473mm from a particular reference point. If `lambda` is changed to `5000Å`, find the position of the zero order and tenth order fringes, other arrangements remaining the same.

In a double slit pattern (lambda = 6000Å) , the first order and tenth order maxima fall at 12.50 mm and 14.75mm from a particular reference point. If lambda is changed to 5500Å, find the position of zero order and tenth order fringes, other arrangements remaining the same.

In a double slit pattern (lambda = 6000Å) , the first order and tenth order maxima fall at 12.50 mm and 14.55mm from a particular reference point. If lambda is changed to 5500Å, find the position of zero order and tenth order fringes, other arrangements remaining the same.

In a double slit pattern (lambda = 6000Å) , the first order and tenth order maxima fall at 12.50 mm and 14.55mm from a particular reference point. If lambda is changed to 5500Å, find the position of zero order and tenth order fringes, other arrangements remaining the same.

In an interference pattern produced by using a biprism, the zeroth order maxima is at a distance of 4.7mm from a point P on the screen. If the fringe width is 0.2 mm, then the distance of the second minima from the point P will be

In an interference pattern the position of zeroth order maxima is 4.8 mm from a certain point P on the screen. The fringe width is 0.2 mm. The position of second maxima from point P is

In Young's double slit experiment, the slits are 0.5mm apart and interference pattern is observed on a screen placed at a distance of 1.0m from the plane containg the slits. If wavelength of the incident light is 6000Å , then the separation between the third bright fringe and the central maxima is