A body of mass 10 mg is moving with a velocity of 100m `s^(-1)`. The wavelength of de-Broglie wave associated with it would be:
(Note : `h = 6.63 xx 10^(-34)` Js)

A body of mass 10 mg is moving with a velocity of 100 ms^(-1) .The wavelength of de-Brogile wave associated with it would be ( h = 6.63 xx 10^(-34) Js)

The de Broglie wavelength of 1 kg mass moving with a velocity of 10 ms^-1 is

A body of mass x kg is moving with a velocity of 100 m/s.Its de Broglie wavelength is 6.62xx10^(-35) m . Hencex is [h=6.2xx10^(-34)Js]

A body of mass x g is moving with a velocity of 100m/s. It de Broglie wavelength is 6.62xx10^(-35)m . Hence x is (h=6.62xx10^(-34)J-s)

(a) The mass of a particle moving with velocity 5xx 10^(6) ms^(-1) has de-Broglie wave length associated with it to be 0.135 nm. Calculate its mass. (b) In which region of the electromagnetic spectrum does this wave length lie?

The momentum of a particle having a de-Broglie wavelenth of 10^(-17) m is ( h=6.625xx10^(-34)Js )

A body of mass 5 kg moving with a velocity of 6 m s^(-1) collide with another body of mass 2 kg which is at rest. Afterwards they move in the same direction as before. If the velocity of the body of mass 2 kg 10 ms^(-1) , find the velocity and kinetic energy to the body of mass 5 kg.

Find the mass of an electrically charged particle movng with a velocity of 3xx 10^(6) ms^(-1) and having a de Brogue wavelength of 2Å.