The wavelength of maximum intensity of radiation emitted by a star is `289.8 nm`. The radiation intensity of the star is
(Stefan's constant `= 5.67 xx 10^(-8) W m^(-2) K^(-4)`. Wien's constant b `= 2898 mum K`)

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 wavelength of the radiation emitted , when in a hydrogen atom electron falls from infinity to stationary state 1 , would be : (Rydberg constant = 1.097 xx 10^(7) m^(-1) )

If wavelength of maximum intensity of radiation emitted by sun and moon are 0.5xx10^(-6) m and 10^(-4) m respectively. Calculate the ratio of their temperatures

Calculate the temperature at which a perfect black body radiates at the rate of 1 W cm^(-2) , value of Stefan's constant, sigma = 5.67 xx 10^(-5) W m^(-2) K^(-8)

If wavelengths of maximum intensity of radiations emitted by the sun and the moon are 0.5xx10^(-6)m " and " 10^(-4) m respectively, the ratio of their temperature is ……………

The wavelength of greatest radiation intensity inside a greenhouse is 9.66xx10^(-6) m. Calculate the corresponding temperature. Wien's constant is 0.00289 mK.

The maximum wavelength of radiation emitted at 2000 K is 4mu m . What will be the maximum wavelength of radiation emitted at 2400K

A body at a temperature of 727^(@)C and having surface area 5 cm^(2) , radiations 300 J of energy each minute. The emissivity is(Given Boltzmann constant =5.67xx10^(-8) Wm^(-2)K^(-4)

Assume that Solar constant is 1.4 kW//m^(2) , radius of sun is 7 xx 10^(5) km and the distance of earth from centre of sun is 1.5 xx 10^(8) km. Stefan's constant is 5.67 xx 10^(-8) Wm^(2) K^(-4) find the approximate temperature of sun

Name the radiations of wavelength just (a) longer than 8 xx 10^(-7) m. (b) shorter than 4 xx 10^(-7) m