The energy distribution E with the wavelength `(lambda)` for the black body radiation at temperature Kelvin T is shown in the figure. As the temperature is increased the maxima will

The rate at which a black body emits radiation at a temperature T is proportional to

The amount of heat energy radiated by a metal at temperature T is E. When the temperature is increased to 3T, energy radiated is

The amount of heat energy radiated by a metal at temperature T is E. When the temperature is increased to 3T, energy radiated is

The amount of heat energy radiated by a metal at temperature T is E. When the temperature is increased to 3T, energy radiated is

The plots of intensity of radiation versus wavelength of 3 black bodies of temperatures T_(1), T_(2) and T_(3) as shown in the figure, then

The graph shows the variation in radiation intensity per unit wavelength versus wavelength for a perfect black- body at temperature T. Complete the following statement: As the blackbody temperature is increased, the peak in intensity of this curve

A black body at a high temperature T radiates energy at the rate of E. When the temperature falls to T/2,the radiated energy will be

A black body is at a temperature of 527^@C , to radiate twice as much energy per second its temperature must be increased to