A particle is moving with kinetic energy E. It's de Broglie wavelength is—

find the de Broglie's wavelength.

If two particles are associated with same kinetic energy, then the de Broglie's wavelength (lamda) of these particles is-

The french physicist Louis de Broglie in 1924 postulated that matter like radiation show a dual behaviour . He proposed the following relationship between the wavelength lambda of a material particle its linear momentum p and planck constant h lamda=h/p =h/(mv) The de broglie relation implies that the wavelength of a particle should decreases as its velocity increases . it also implies that for a given velocity heavier particles should have shorter wavelength than lighter particles. The waves associated with particles in motion are called matter waves or de broglie waves. These waves differ from the electromagnetic waves as they (i) have lower velocities (ii) have no electrical and magnetic fields and (iii) are not emitted by the particle under consideration . The experimental confirmation of the de-broglie relation was obtained when Davisson ans Germer in 1927 observed that a beam of electrons is diffracted by a nickel crystal . as diffraction a characteristics property of waves hence the beam of electron behaves as a wave, as proposed by de-broglie. If proton, electron and alpha -particle are moving with same kinetic energy then the order of de-Broglie's wavelength

Write down the relationship between wavelength and energy of a photon? If a proton and an alpha particle is moving with the same kinetic energy, then what is the relationbetween their de Broglie wave length?

Show that, the relation between kinetic energy and the de-broglie wavelength associated with a moving electron is X = h/(sqrt2mE

Derive a relation between kinetic energy and de Broglie wavelength associated with a moving electron.

A moving electron has 4.9 xx 10^(-25) joules of kinetic energy. Find out its de - Broglie wavelength (Given h = 6.626 xx 10^(-34) Js, m_e = 9.1 xx 10^(-31) kg).

Statement I: If the kinetic energy of particles with different masses are same, then the de Broglie wavelength of the particles are inversely proportional to their mass Statement II: Momentum of moving particles is inversely proportional to their de Broglie wavelengths.

What should be the percentage increase or decrease of kinetic energy of an electron so that its de Broglie wavelength is halved?

Two particles P and Q are moving with the same velocity, but de broglie wavelength of P is thrice that of Q. what do you conclude?