Answer to Question #114899 in Quantum Mechanics for chandan

By definition, the deBroglie wavelength is given by:

"\\lambda = \\dfrac{h}{p}" , where "h = 6.6\\cdot 10^{-34} J\\cdot s" is the Planck constant and "p" is the momentum of the electron. In the relativistic case:

"p = \\dfrac{mv}{\\sqrt{1-\\frac{v^2}{c^2}}}" , where "m = 9.1\\cdot 10^{-31} kg" is the electon mass, "c = 3\\cdot 10^8" speed of light in vacuum and "v" is the electron speed.

Finaly obtain:

"\\lambda = \\dfrac{h}{mv}\\sqrt{1-\\frac{v^2}{c^2}}" .

Substitute numerical values:

a) "\\lambda = \\dfrac{6.6\\cdot 10^{-34}}{9.1\\cdot 10^{-31}\\cdot 1\\cdot10^8}\\sqrt{1-\\frac{1\\cdot10^{16}}{9\\cdot 10^{16}}} = 6.84\\cdot 10^{-12} m"

b) "\\lambda = \\dfrac{6.6\\cdot 10^{-34}}{9.1\\cdot 10^{-31}\\cdot 2\\cdot10^8}\\sqrt{1-\\frac{4\\cdot10^{16}}{9\\cdot 10^{16}}} = 2.7\\cdot 10^{-12} m"