368059 In Young’s double slit experiment, the ratio of intesities of bright and dark bands is 16 which means

368060 Assertion :
Given, In Young's double slit experiment the two slits are at distance \(d\) apart. Interference pattern is observed on a screen at distance \(D\) from the slits. At a point on the screen when it is directly opposite to one of the slits, first dark fringe is observed.
Reason :
The wavelength of wave is proportional to square of distance of two slits.

368061 In a Young’s double slit experiment, a student observes 8 fringes in a certain segment of screen when a monochromatic light of \(600\;nm\) wavelength is used. If the wavelength of light is changed to \(400\;nm\) , then the number of fringes he would observe in the same region of the screen is

368062 Two slits are seperated by \(0.3\,mm\). A beam of \(500\,mm\) light strikes the slits producing an interference pattern. The number of maxima observed in the angular range \(-30^{\circ} < \theta < 30^{\circ}\).

368063 The path difference between two interfering light waves meeting at a point on the screen is \(\left(\dfrac{87}{2}\right) \lambda\). The band obtained at that point is

368059 In Young’s double slit experiment, the ratio of intesities of bright and dark bands is 16 which means

368060 Assertion :
Given, In Young's double slit experiment the two slits are at distance \(d\) apart. Interference pattern is observed on a screen at distance \(D\) from the slits. At a point on the screen when it is directly opposite to one of the slits, first dark fringe is observed.
Reason :
The wavelength of wave is proportional to square of distance of two slits.

368061 In a Young’s double slit experiment, a student observes 8 fringes in a certain segment of screen when a monochromatic light of \(600\;nm\) wavelength is used. If the wavelength of light is changed to \(400\;nm\) , then the number of fringes he would observe in the same region of the screen is

368062 Two slits are seperated by \(0.3\,mm\). A beam of \(500\,mm\) light strikes the slits producing an interference pattern. The number of maxima observed in the angular range \(-30^{\circ} < \theta < 30^{\circ}\).

368063 The path difference between two interfering light waves meeting at a point on the screen is \(\left(\dfrac{87}{2}\right) \lambda\). The band obtained at that point is

368059 In Young’s double slit experiment, the ratio of intesities of bright and dark bands is 16 which means

368060 Assertion :
Given, In Young's double slit experiment the two slits are at distance \(d\) apart. Interference pattern is observed on a screen at distance \(D\) from the slits. At a point on the screen when it is directly opposite to one of the slits, first dark fringe is observed.
Reason :
The wavelength of wave is proportional to square of distance of two slits.

368061 In a Young’s double slit experiment, a student observes 8 fringes in a certain segment of screen when a monochromatic light of \(600\;nm\) wavelength is used. If the wavelength of light is changed to \(400\;nm\) , then the number of fringes he would observe in the same region of the screen is

368062 Two slits are seperated by \(0.3\,mm\). A beam of \(500\,mm\) light strikes the slits producing an interference pattern. The number of maxima observed in the angular range \(-30^{\circ} < \theta < 30^{\circ}\).

368063 The path difference between two interfering light waves meeting at a point on the screen is \(\left(\dfrac{87}{2}\right) \lambda\). The band obtained at that point is

368059 In Young’s double slit experiment, the ratio of intesities of bright and dark bands is 16 which means

368060 Assertion :
Given, In Young's double slit experiment the two slits are at distance \(d\) apart. Interference pattern is observed on a screen at distance \(D\) from the slits. At a point on the screen when it is directly opposite to one of the slits, first dark fringe is observed.
Reason :
The wavelength of wave is proportional to square of distance of two slits.

368061 In a Young’s double slit experiment, a student observes 8 fringes in a certain segment of screen when a monochromatic light of \(600\;nm\) wavelength is used. If the wavelength of light is changed to \(400\;nm\) , then the number of fringes he would observe in the same region of the screen is

368062 Two slits are seperated by \(0.3\,mm\). A beam of \(500\,mm\) light strikes the slits producing an interference pattern. The number of maxima observed in the angular range \(-30^{\circ} < \theta < 30^{\circ}\).

368063 The path difference between two interfering light waves meeting at a point on the screen is \(\left(\dfrac{87}{2}\right) \lambda\). The band obtained at that point is

368059 In Young’s double slit experiment, the ratio of intesities of bright and dark bands is 16 which means

368060 Assertion :
Given, In Young's double slit experiment the two slits are at distance \(d\) apart. Interference pattern is observed on a screen at distance \(D\) from the slits. At a point on the screen when it is directly opposite to one of the slits, first dark fringe is observed.
Reason :
The wavelength of wave is proportional to square of distance of two slits.

368061 In a Young’s double slit experiment, a student observes 8 fringes in a certain segment of screen when a monochromatic light of \(600\;nm\) wavelength is used. If the wavelength of light is changed to \(400\;nm\) , then the number of fringes he would observe in the same region of the screen is

368062 Two slits are seperated by \(0.3\,mm\). A beam of \(500\,mm\) light strikes the slits producing an interference pattern. The number of maxima observed in the angular range \(-30^{\circ} < \theta < 30^{\circ}\).

368063 The path difference between two interfering light waves meeting at a point on the screen is \(\left(\dfrac{87}{2}\right) \lambda\). The band obtained at that point is