Light of wavelength `520nm` passing through a double slit,produced interference pattern of relative intensity versus deflection angle `theta` as shown in the figure.find the separation of between the slits.

In young's double slit experiment relative intensity at a point on the screen may be defined as ratio of intensity at that point to the maximum intensity on the screen. Light of wavelength 7500overset(@)A A passing through a double slit, produces interference pattern of relative intensity variation as shown in Fig. theta on horizontal axis represents the angular position of a point on the screen (a) Find separation d between the slits. (b) Find the ratio of amplitudes of the two waves producing interference pattern on the screen.

A monochromatic light of wavelenght 5000Å passes through a single slit producing diffraction pattern for the central maximum as shown in the figure. Determine that width of the slit.

Laser light of wavelength 630 nm incident on a pair of slits produces an interference pattern where bright fringes are separated by 8.1 mm . Another light produces the interference pattern, where the bright fringes are separated by 7.2 mm . Calculate the wavelength of second light.

Laser light of wavelength 630 nm incident on a pair of slits produces an interference pattern where bright fringes are separated by 8.1 mm . Another light produces the interference pattern, where the bright fringes are separated by 7.2 mm . Calculate the wavelength of second light.

A source emitting light of wavelengths 480 nm and 600 nm is used in a double slit interference experiment. The separation between the slits is 0.25 mm and the interference is observed on a screen placed at 150 cm from the slits. Find the linear separation between the first maximum (next to the central maximum) corresponding to the two wavelengths.

A source emitting light of wavelengths 480 nm and 600 nm is used in a double slit interference experiment. The separation between the slits is 0.25 mm and the interference is observed on a screen placed at 150 cm from the slits. Find the linear separation between the first maximum (next to the central maximum) corresponding to the two wavelengths.

A source emitting light of wavelengths 480 nm and 600 nm is used in a double slit interference experiment. The separation between the slits is 0.25 mm and the interference is observed on a screen placed at 150 cm from the slits. Find the linear separation between the first maximum (next to the central maximum) corresponding to the two wavelengths.