A star which is emitting radiation at a wavelength of 5000A is approaching the earth with a velocity of `1.50 xx10^(6) m//s` The change in wavelegth of the radiation as received on the earth is

A star emitting light of wavelength 6000 Å is moving towards the earth with a speed of 3 xx 10^(6) m//s . What is the apparent wavelength of the emitted light ?

An electron of work function 1.4 eV is emitted with a velocity 5 xx 10^(6) m/s . The wavelength of the incident radiation is

A star emits a light of wavelength I and it is receding from the earth with a velocity v_(s) . The shift in wavelength of spectral line observed on earth is

A star is moving away from the earth with a velocity of 10^(5) m/sec. If wavelength of its spectral line be 5700 Å , the Doppler's shift will be

The energy of incident radiation, which emits the electrons with a velocity of 2.5 xx 10^(6) m/s and work function 1.8 e V , is

The photoelectron of work function 3.1 eV is emitted with velocity 2.5 xx 10^(6) m/s . The frequency of incident radiation is

A star, emitting green light, is approaching the earth with uniform acceleration . The colour of the light received from this star, as observed by stationary observer on the earth, would be -

star emitting light of wavelength 5896 Å is moving away from the earth with a speed of 3600 km / sec . The wavelength of light observed on earth will ( c= 3 xx 10 ^(8) m//sec is the speed of light)

The maximum wavelength of radiation emitted from the sun at 6000 K is about 550 nm. What would be the wavelength of maximum radiation emitted from the earth at 27^(@)C ?