The thermal radiation emitted by a body per second per unit area is `(DeltaH)/(A Deltat)=kT^(4)`. If `sigma` is Stefan's constant, then body

The radiation emitted per unit time by unit area of a black body at temperature T is sigmaT^(4) wehre sigma is the Stefan-Boltzmann constant. The constant sigma can also be expressed in terms of Boltmann's constant (k), Planck's constant (h) and speed of light (3) as sigma=Ak^(alpha)h^(beta)c^(gamma) where A, alpha,beta and gamma are dimensionless constants. The set (alpha,beta,gamma) is givne by

The amount of radiations emitted per second by unit area of a hollow container at 10^(3^(@)) K will be-

The thermal radiation emited bby a body is propertional to T^(n) where T is its absolute temperature. The value of n is exanctly 4 for

Assuming the Sun to be a spherical body of radius R at a temperature of TK, evalute the total radiant powerd incident of Earth at a distance r from the sun where r_0 is the radius of the Earth and sigma is Stefan's constant.

A spherical body of emissivity e, placed inside a perfectly black body (emissivity = 1) is maintained at absolute temperature T. The energy radiated by a unit area of the body per second will be ( sigma is Stefan's constant)

The change in momentum per unit time of body represents .

The amount of thermal radiations emitted from one square centimetre area of a black body in one second when at a temperature of 1000 K is:

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

The power emitted per unit area of a black body is R watt/ m^2 . At what wavelength will the power radiated by the black body be maximum. If the Stefan's constant is sigma and Wien's constant is b, then