The ratio of the wavelength of emission corresponding to the maximum emission in the spectrum of a black body heated to temperatures 1000 K and 2000 K respectively is

Emissive power of a perfectly black body

Rates of emission of heat by perfectly black body maintained at temperatures 27° C and 927° C are in ratio

What emissive power of perfectly black body ?

Two bodies A and B having same surface areas have emmissivities of 0.01 and 0.49 respectively. The two bodies emit total radiant power at the same rate. The wavelength A8 corresponding to maximum spectral radiancy 111 the radiation from B shifted from the wavelength corresponding to maximum spectral radiancy in the radiation from A by 1 µm. Jf temperature of A is 5200 K then,

Two perfect black bodies A_1 and A_2 made out of same material have diameters 2 cm and 16 cm respectively. lamda_("max")^' and lamda_("max")^'' are the wavelengths corresponding to their maximum radiation of energy at a common temperature lamda_("max")^' and lamda_("max")^'' are related as

The light from the sun is found to have a maximum intensity near the wavelength of 470 nm. Assuming the surface of the sun as a black body, the temperature of the sun is

A metal surface is illuminated by light of two different wavelengths 248 nm and 310 nm. The maximum speeds of the photoelectrons corresponding to these wavelengths are mu_1 and mu_2 respectively. If the ratio u_1: u_2 = 2:1 and hc= 1240 eV , the work function of the metal is nearly.

A metal cube of length 10 cm radiates heat at the rate of 60 watt. Find its emissive power of a perfectly black body at that temperature.

If the wavelength corresponding to maximum energy radiated from the moon is 14 micron , and Wien 's constant is 2.8 xx 10^(-3) m K , then temperature of moon is