If the enrgy of a frequency v is gives by `E = hv` where `h` is plank's constant and the momentum of photon is `p = h//lambda` where `lambda ` is the wavelength of photon , then the velocity of light is equal to

We can say that the energy of a photon of frequency v is given by E = hv, where h is planck's constant. The momentum of a photon is p = h//lambda, where lambda is the wavelenght of photon, then we may conclude that velocity of light is equal to

We may state that the energy E of a photon of frequency v is E =hv, where h is a plank's constant. The momentum p of a photon is p=h//lambda where lambda is the wavelength of the photon. From the above statement one may conclude that the wave velocity of light is equal to

We may state that the energy E of a photon of frequency nu is E =hnu , where h is a plank's constant. The momentum p of a photon is p=h//lambda where lambda is the wavelength of the photon. From the above statement one may conclude that the wave velocity of light is equal to

If h is Planck's constant, find the momentum of a photon of wavelength 0.1Å .

If h is Plank's constant. Find the momentum of a photon of wavelength 0.01Å.

If h is Plank's constant. Find the momentum of a photon of wavelength 0.01Å.

The momentum of a photon of wavelength lambda is

The momentum of a photon of wavelength lambda is