If a proton and an electron are confined to the same region, then uncertainity in momentum

Assuming an electron is confined to a 1 nm wide region. Find the uncertainty in momentum using Heisenberg uncertainty principle. ("Take h"=6.63xx10^(-34)Js)

If a proton and electron have the same de Broglie wavelength, then

Assuming an electron is confined to a 1nm wide region, find the wavelength in momentum using Heisenberg Uncetainity principal (Deltax Deltap~~h) . You can assume the uncertainity in position Deltax and 1nm. Assuming p~=Deltap , find the energy of the electron in electron volts.

Do protons and electrons have same mass?

If the uncertainity in the position of an electron is 10^(-10) m , then the value of uncertainity in its momentum (in kg-ms^(-1) ) will be

A proton and an electron both moving with the same velocity v enter into a region of magnetic field directed perpendicular to the velocity of the particles. They will now move in cirular orbits such that

The uncertainity in the positions of an electron and proton is equal, the ratio of the uncertainities in the velocity of an electron and proton is

A proton and an electron are projected into a region of uniform magnetic field in a direction perpendicular to the field. If they have the same initial velocities then

A proton and an electron are accelerated by the same potential difference, let lambda_(e) and lambda_(p) denote the de-Broglie wavelengths of the electron and the proton respectively