[" 1.The wavelength "lambda" associated with a moving electron "],[" depends on its mass "m" ,its velocity "v" and Planck's "],[" constant "h" .Prove dimensionally that "lambda prop(h)/(mv)" ."]

The wavelength lambda associated with a moving particle depends upon its mass m, its velocity v and Planck’s constant h Show dimensionally the relationship between them

The wavelength lambda associated with a moving particle depends upon its mass (m) velocity (v) and Planck's constant 'h'. Show dimensionally that lambda prop (h)/(mv) .

The wavelength of matter waves associated with an electron of mass m having kinetic energy E is given by (h is Planck's constant)

The wavelength associated with a moving particle depends upon p^(th) power of its mass m, q^(th) power of its velocity v and power of plank's constant h Then the corrent set of valume of p,q and r is

According to de-Broglie hypothesis, the wavelength associated with moving electron of mass 'm' is 'lambda_(e)' . Using mass energy relation and Planck's quantum theory, the wavelength associated with photon is 'lambda_(p)' . If the energy (E) of electron and photonm is same, then relation between lambda_e and 'lambda_(p)' is

If a light of wavelength lambda hits moving electron the uncertainty in measurement of its position will be

If the de-Broglie wavelength of a particle of mass m is 100 times its velocity then its value in terms of its mass (m) and Planck's constant (h) is

If the de-Broglie wavelength of a particle of mass m is 100 times its velocity then its value in terms of its mass (m) and Planck's constant (h) is