For the same objective, the ratio of least separation between two points to be distinguished by a microscope for light of `5000 Å` and electrons accelerated through 100V used as illuminating substance is __________ (nearly)

For the same objective, the ratio of least separation between two points to be distiguised by a microscope for light of 5000 Å and electrons acclerated through 100V used as illuminating substance is __________ (neraly)

For the same objective, what is the ratio of the least separation between two points to be distinguished by a microscope for light of 5000 Ã… and electrons accelerated through 100 V used as an illuminating substance?

The wavelength associated with an electron accelerated through a potential difference of 100 V is nearly

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 diameter of human eye lens is 2 mm . What should be the minimum separation between two points situated at 50 m from eye, to resolve tham. Take wavelength of light = 5000 Å .

The diameter of human eye lens is 2 mm . What should be the minimum separation between two points situated at 50 m from eye, to resolve tham. Take wavelength of light = 5000 Å .

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

The ratio of the deBroglie wavelengths of proton, deuteron and alpha particle accelerated through the same potential difference 100V is

The limit of resolution of a microscope is the least distance between two point objects which can be seen clearly and distinctively with it. For a naked eye, limit of resolution is about 10^(-4) m or 0.1 mm. The limit of resolution for a microscope is of the order of lambda/2 , where lambda is wavelength of light used. For an optical microscope , using visible light, limit of resolution is "500 nm"/2 =250 mm. This is 400 times smaller than naked eye. So the useful magnification produced by it is 400. Smaller is the limit of resolution, greater is the magnification that can be achieved. By using shorter wavelengths , we can improve resolution. For examination of a microorganism, much higher limit of resolution is needed, the Wave nature of electron provides a means for probes of very small size organisms. An electron beam accelerated by a high potential difference possess a very short wavelength. In an electron microscope magnetic lenses are used to control the path of electrons. The image of object is obtained on a fluorescent screen or on a photographic plate. The electron microscope with its high magnifying power and resolving power , is one of the most indispensable and powerful tool for research in science , medicine and industry. For an electron beam accelerated through a high potential difference V, limit of resolution is proportional to

A wave travelling along the length of a string is shown in Fig. 14.4.12. Using the scale on the given axis, find (i) The amplitude of the wave (ii) The wavelength of the wave (iii) If the frequency of the wave is 10 Hz, What is the speed of the wave? (iv) What is the initial phase of the wave ? (v) What is the phase difference between two points separated by a distance 10 cm ? (vi) If this wave is made to travel through water what is the wavelength of the wave, if the speed of, the waves in water is 10 m/s.