A distant star emits radiation with maximum intensity at 350 nm. The temperature of the star is

A heated body emits radiation which has maximum intensity near the frequency v_(0) The emissivity of the material is 0.5 . If the absolute temperature of the body is doubled,

If the radius of a star is R and it acts as a block body . What would be the temperature of the star, in which the rate of energy production is Q?

A cubical block of mass 1.0kg and edge 5.0cm is heated to 227^(@)C . It is kept in an evacuated chamber maintained at 27^(@)C . Assming that the block emits radiation like a blackbody, find the rate at which the temperature of the block will decreases. Specific heat capacity of the material of the block is 400Jkg^(-1)K^(-1) .

One end of a rod length 20cm is inserted in a furnace at 800K. The sides of the rod are covered with an insulating material and the other end emits radiation like a blackbody. The temperature of this end is 750K in the steady state. The temperature of the surrounding air is 300K. Assuming radiation to be the only important mode of energy transfer between the surrounding and the open end of the rod, find the thermal conductivity of the rod. Stefan constant sigma=6.0xx10^(-1)Wm^(-2)K^(-4) .

The wavelength of maximum intensity of radiation emitted by a star is 289.8nm. The radiation intensity for the star is (Stefan's constant = 5.67×10^-8Wm^-2K^-4 , constant b = 2898mumK ).

The ionization energy of the electron in the hydrogen atom in its ground state is 13.6 eV. The atoms are excited to higher energy levels to emit radiations of 6 wavelengths. Maximum wavelength of emitted radiation corresponds to the transition between

The band gap between the valence and the conduction bands in zinc oxide (ZnO) is 3.0eV.Suppose an electron in the conduction band combines with a hole in the valence band and the excess energy is released in the form of electromagnetic radiation .Find the maximum wavelength that can be emitted in this process.

In a Young's double slit experiment, the separation between the slits = 2.0 mm, the wavelength of the light = 600 nm and the distance of the screen from the slits = 2.0 m. If the intensity at the centre of the central maximum is 0.20 W m^-2 , what will be the intensity at a point 0.5 cm away from this centre along the width of the fringes ?

The light from the sun is found to have a maximum intensity near the wavelength of 470nm. Assuming that the surface o f the sun emits as a blackbody, calculate the temperature of the surface of the sun.

A thin paper of thickness 0.02 mm having a refractive index 1.45 is pasted across one of the slits in a YDSE. The paper transimits 4//9 of the light energy falling on it. a. Find the ratio of maximum intensity to the minimum intensity in interference pattern. b. How many fringes will cross through the center if an indentical paper piece is pasted on the other slit also? The wavelength of the light used is 600 nm.