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

If the energy of a photon is E, then its momentum is (c is velocity of light )

Momentum of a photon of wavelength lambda is :

What is the momentum (p) of photon from ultraviolet light of wavelength lambda= 332 nm.

The relation between the "energy" E and the frequency v of a photon is repressed by the equation E = hv , where h is plank's constant Write down its dimensions.

The velocity of photon is proportional to (where v is frequency)

If energy of photon is Eproph^(a)c^(b)lamda^(d) . Here h= Planck's constant c= speed of light and lamda= wavelength of photon Then, the value of a,b and d are

The energy of a photon is equal to the kinetic energy of a proton. The energy of the photon is E. Let lambda_1 be the de-Broglie wavelength of the proton and lambda_2 be the wavelength of the photon. The ratio (lambda_1)/(lambda_2) is proportional to (a) E^0 (b) E^(1//2) (c ) E^(-1) (d) E^(-2)

Find the dimensions of Planck's constant h from the equatioin E=hv where E is the energy and v is the frequency.