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

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

A light has a wavelength 6000Å. The energy of this light is

By using light of wavelength 5200 Å, two points separated by a distance of 0.12 mm can just be resolved by a microscope. What will be the limit of resolution, if light of wavelength 6500 Å is used?

The fringe width in a biprims experiment is 0.32 mm, when red light of waelength 6400Å is used. If source of blue light of wavelength 4000Å is used with the same setting, then the fringe width will

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 a biprism experiment, the distance between the consecutive bright bands is 0.32 mm, when red light of wavelength 6400 Å is used. By how much would the band width change, if blue light of wavelenth 4800 Å is used, with the same setting?

Light of wavelength 6000 Å falls on a plane reflecting surface. The reflected wavelength is.

Light of wavelength 6000Å falls on a plane reflecting surface. The reflected wavelength is

The numerical aperture of objective of a microscope is 1*12 . The limit of resolution, when light of wavalength 6000 Å is used to view an object is :