The wave length of maximum emitted energy of a body at 700 K is `4.08 `mu` m . If the temperature of the body is raised to 1400 K, the wavelength of maximum emitted energy will be

If the temperature of any ideal black body is halved, then the wavelength of maximum emission will be

The wavelength of a particle of mass m and energy E_K will be

A black body emits radiations of maximum intensity at a wavelength of 5000 A, when the temperature of the body is 1227° C. If the temperature of the body is increased by 2227 °C, the maximum intensity of emitted radiation would be observed at

If the temperature of a hot body is increased by 50% then amount of radiant energy emitted by it increases approximately by

The value of wavelength of maximum energy by a blackbody is inversely proportional to the absolute temperature. This law is

The power radiated by a black body is P, and it radiates maximum energy around the wavelength lambda_(0) . If the temperature of the black body is now changed so that it radiates maximum energy around a wavelength 3lambda_(0)//4 , the power radiated by it will increase by a factor of

The maximum wavelength of radiation emitted by a black body at 1227 ^@C is Am. What is its maximum wavelength at 2227 ^@C ?

The maximum wavelength of radiation emitted at 1500K is 5mum . The maximum wavelength of radiation emitted at 2500 K will be

If the surface temperature of the sun is assumed to be 6150 K, find the wave length of maximum intensity in the sun’s radiation taking Wien's constant 2.88 xx 10^-3mk .