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

Two spheres P and Q of the same colour having radii 8 cm and 2 cm respectively are maintained at temperatures 127^@C and 527^@C respectively. Then the ratio of the energy radiated by Pand Q is

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 spherical black bodies of radii R_(1) and R_(2) and with surface temperature T_(1) and T_(2) respectively radiate the same power. R_(1)//R_(2) must be equal to

A star radiates maximum radiation at wavelength lamda_m at temperature T. What will be the temperture of another star which radiates maximum energy of wavelength 2lamda_m ?

The energy spectrum of a black body exhibits a maximum around a wavelength lamda_0 . The temperature of the black body is now changed such that the energy is maximum around a wavelength 3 lamda_0//4 . The power radiated by the black body will now increase by a factor of

Assertion: Work function of a metal is 5 eV. The maximum wavelength of photons required to emit electrons from its surface is 2480 Å. Reason: Work function, phi_0=(hc)/lamda_max .

A black body at 227^(@)C radiates heat at the rate of 7 cal cm^(-2) s^(-1) . At a temperature of 727^(@)C , the rate of heat radiated in the same unit will be