The maximum energy in thermal radiation from a source occurs at the wavelength 4000Å. The effective temperature of the source

The temperature of sun is 5500 K and it emits maximum intensity radiation in the yellow region (5.5 xx10^(-7)m) . The maximum radiation from a furnace occurs at wavelength 11 xx 10^(-7)m The temperature of furnace is

The sun radiates maximum energy at wavelength 4753Å . The surface temperature of the sun if b=2.888xx10^(-3)mK , is

Calculate the frequency corresponding to the wavelength 4000 Å

A black body at 1227^(@)C emits radiations with maximum intensity at a wavelength of 5000 Å . If the temperature of the body is increased by 1000^(@) , the maximum intensity will be observed at

For an enclosure maintained at 2000K, the maximum radiation occurs at wavelength lambda_m . If the temperature is raised to 3000K, the peak will shift to

A black body at 1500K emits maximum energy of wavlength 20000 Å . If sun emits maximum energy of wavelength 5500Å , what would be the temperature of sun.

Wien's law is concerned with: (a) wavelength corresponding to maximum energy and absolute temperature. (b) radiated energy and wavelength. (c) emissive power and temperature. (d) colour of light and temperature.

Calculate the energy associated with one photon of the radian of wavelength 4000Å.

In the photoelectric effect, the maximum speed of electrons is found to be 6xx10^(5)ms^(-1) . The wavelength used is 4000Å . The work function of the metal is

A black body emits radiations of maximum intensity at a wavelength of Å 5000 , when the temperature of the body is 1227^(@)C . If the temperature of the body is increased by 1000^(@)C , the maximum intensity of emitted radiation would be observed at