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

The famous Stefan's law of radiation states that the rate of emission of thermal radiation per unit by a black body is proportional to area and fourth power of its absolute temperature that is Q=sigmaAT^(4) where A = area, T = temperature and sigma is a universal constant. In the 'energy-length-time temperature' (E-L-T-K) system the dimension of sigma is

The amount of thermal radiation energy emitted from the surface of a body is found to be proportional to the ........ power of the absolute temperature of the body.

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

Assertion : The radiation from the sun’s surface varies as the fourth power of its absolute temperature. Reason : The sun is not a black body.

The spectra of radiation emitted by two distant stars are shown below The ratio of the surface temperature of star A to that of star B, T_(A) :T_(B) is approximately .

The spectra of radiation emitted by two distant stars are shown below. The ratio of the surface temperature of star A to that of star B, T_(A):T_(B), is approximately-

The amount of thermal radiations emitted from one square metre area of a black body in one second when at a temperature of 100 K is

Two ends of a rod of uniform cross sectional area are kept at temperature 3T_(0) and T_(0) as shown. Thermal conductivity of rod varies as k=alphaT , (where alpha is a constant and T is absolute temperature). In steady state, the temperature of the middle section of the rod is