Assertion:- In standard YDSE set up with visible light, the position on screen where phase difference is zero appears bright.
Reason:- In YDSE set up magnitude of electromagnetic field at central bright frings is not varying with time.

In a standard YDSE set up,the intensity at a point where phase difference between the light from the slits is (pi)/(3) is I_(0) .The intensity of central maximum will be ?

Assertion : In YDSE bright and dark fringe are equally spaced. Reason : It only depends upon phase difference.

Assertion In the YDSE set up shown in figure a glass slab is inserted in front of the slit S_(1) as shown in figure Then zero order maxima (where path difference =0) will lie above point O. Reason Glass slab will produce an extra path difference in the path of the ray passing through S_(1)

Assertion: When two ends of a metallic wire are connected across the terminals of a cell, then some potential difference is set up the corresponding of between its ends. The direction of electrons are from positive terminal to negative terminal of correct answer as the cell. Reason: Electrons are flowing through the conductors from its higher potential to its lower potential end.

In a standard YDSE slit width is 1mm and distance of screen from the slit is 1m. If wavelength of light is 632nm and bright fringe formed at y = 1.270 mm. Find path difference for the point

A vessel ABCD of 10 cm width has two small slits S_(1) and S_(2) sealed with idebtical glass plates of equal thickness. The distance between the slits is 0.8 mm . POQ is the line perpendicular to the plane AB and passing through O, the middle point of S_(1) and S_(2) . A monochromatic light source is kept at S, 40 cm below P and 2 m from the vessel, to illuminate the slits as shown in the figure. Calculate the position of the central bright fringe on the other wall CD with respect of the line OQ . Now, a liquid is poured into the vessel and filled up to OQ . The central bright fringe is fiund to be at Q. Calculate the refractive index of the liquid.

A beam of light consisting of wavelengths 6000 Å and 4500 Å is used in a YDSE with D = 1 m and d = 1 mm. Find the least distance from the central maxima, where bright fringes due to the two wavelengths coincide.