Calculate the radius of the first Bohr orbit of a `He^(+)` ion and the binding energy of its electron in the ground state.

Calculate the radius of the third Bohr orbit of hydrogen atom and the energy of electron in that orbit.

Calculate the radius of Bohr's 3rd orbit in Li^(+2) ion

A mu-meson ("charge -e , mass = 207 m , where m is mass of electron") can be captured by a proton to form a hydrogen - like ''mesic'' atom. Calculate the radius of the first Bohr orbit , the binding energy and the wavelength of the line in the Lyman series for such an atom. The mass of the proton is 1836 times the mass of the electron. The radius of the first Bohr orbit and the binding energy of hydrogen are 0.529 Å and 13.6 e V , repectively. Take R = 1.67 xx 109678 cm^(-1)

Calculate the energy of an electron in the first Bohr orbit of He^(+) .

a. Calculate the radius of Bohr's first orbit for hydrogen atom and the energy of electron in this orbit . b. Calculate the Bohr's radius for the fifth orbit of the hydrogen atom

If the radius of the first Bohr orbit of the H atom is r then for the Li^(2+) ion it will be:

Calculate the radius of the first Bohr orbit in the hydrogen atom. Hence calculate the radius of the second orbit.

Calculate for a hudrogen atom and a He^(+) ion: (a) the radius of the first Bohr orbit and velocity of an electron moving along it , (b) the kineric energy and the binding energy of an electron in the ground state, (c ) the ironizartion potential, the first excitaion potential and the wavelength of the resonance line ( n' =2 rarr=1)

Calculate the energy of an electron in the second Bohr's orbit of an excited hydrogen atom the energy of electron in the first Bohr orbit is -2.18 xx 10^(-11) erg