Figure shows a standard two slit arrangement with slits `S_(1),S_(2).P_(1),P_(2)` are the two minima points on either side of P. At `P_(2)` on the screen, there is a hole and behind `P_(2)` is a second 2 -slit arrangement with slits `S_(3), S_(4)` and a second screen behind them.

Figure shows a standard two slit arrangement with slits S_(1), S_(2). P_(1), P_(2) are the two minima points on either side of P (Figure). At P_(2) on the screen, there is a hole and behind P_(2) is a second 2-slit arrangement with slits S_(3), S_(4) and a second screen behind them.

Figure shows a standard two slit arrangement with slits S_(1), S_(2). P_(1), P_(2) are the two minima points on either side of P (Figure). At P_(2) on the screen, there is a hole and behind P_(2) is a second 2-slit arrangement with slits S_(3), S_(4) and a second screen behind them.

In the arrangement shown in Fig., slits S_(1) and S_(4) are having a variable separation Z. Point O on the screen is at the common perpendicular bisector of S_(1) S_(2) and S_(3) S_(4) . The minimum value of Z for which the intensity at O is zero is

In a Young's double slit experiment, let S_(1) and S_(2) be the two slits, and C be the centre of the screen. If angle S_(1)CS_(2)=theta and lambda is the wavelength, the fringe width will be

In the arrangement shown in Fig., slits S_(1) and S_(4) are having a variable separation Z. Point O on the screen is at the common perpendicular bisector of S_(1) S_(2) and S_(3) S_(4) . If a hole is made at O' on AO' O and the slit S_(4) is closed, then the ratio of the maximum to minimum observed on screen at O , if O' S_(3) is equal to (lambda D)/(4d) , is

While conduction the Young's double slit experiment, a student replaced the two slits with a large opaque plate in the x-y plane containing two small holes that act as two coherent point sources (S_(1),S_(2)) emitting light of wavelength 600nm. The student mistakenly placed the screen parallel to the x-z plane (for zgt0) at a distance D=3 m from the mid-point of S_(1) , S_(2) , as shown schematically in the figure. The distance between the sources d=0.6003 mm . The origin O is at the intersection of the screen and the line joining S_(1)S_(2) . Which of the following is (are) true of the intensity pattern of the screen?

S_(1) and S_(2) are two equally intense coherent point second sources vibrating in phase. The resultant intensity at P_(1) is 80 SI units then resultant intensity at P_(2) in SI units will be

In the above problem, minimum value of t for which the intensity at point P on the screen exactly in front of the upper slit becomes maximum.

In P Q R , S is any point on the side Q R . Show that P Q+Q R+R P >2P S

In a Young’s double slit experiment, the separation of the two slits is doubled. To keep the same spacing of fringes, the distance D of the screen from the slits should be made