Two points separated by a distance of 0.1 mm can just be inspected in a microscope when light of wavelength 6000 Ã… is used. If the light of wavelength 4800 Ã… is used then limit of resolution will become

Two points separated by a distance of 0.1mm can just be resolved in a microscope when a light of wavelength 6000Å is used. If the light of wavelength 4800Å is used this limit of resolution becomes

The fringe width in YDSE is 2.4 xx 10^(-4)m , when red light of wavelength 6400 Å is used. By how much will it change, if blue light of wavelength 4000 Å is used ?

In Young's double slit experiment, when light of wavelength 4000 A^(@) is used 90 fringes are seen on the screen. When light of 3000 A is used, the number of fringes seen is

Two slits are separated by a distance of 0.5mm and illuminated with light of lambda=6000Å . If the screen is placed 2.5m from the slits. The distance of the third bright image from the centre will be

The numerical aperture of an objective of a microscope is 0.5 and the wavelength of light used is 5000 A^(0) . Its limit of resolution will be

In Young's double slit experiment, we get 60 fringes in the field of view of monochromatic light of wavelength 4000Å . If we use monochromatic light of wavelength 6000Å , then the number of fringes obtained in the same field of view is

The value of numerical aperature of the objective lens of a microscope is 1.25 if light of wavelength 5000 Å is used the minimum separation between two points to be seen as distinct, will be

In Young's double-slit experiment, 30 fringes are obtained in the field of view of the observing telescope, when the wavelength of light used is 4000 Å . If we use monochromatic light of wavelength 6000 Å , the number of fringes obtained in the same field of view is

Two coherent sources are 0.15 mm apart and fringes are observed 1m away with monochromatic light of wavelength 6000^(0) . Find The fringe width in air.

In a Young's double slit experiment with slit separation 0.1 mm, one observes a bright fringe at angle (1)/(40) rad by using light of wavelength lamda_(1). When the light of wavelength lamda_(2) is used a bright fringe is seen at the same angle in the same set up. Given that lamda_(1) and lamda_(2) are in visible range (380 nm to 740 nm), their values are :