An electron changes its position from orbit n = 4 to the orbit n = 2 of an atom. The wavelength of the emitted radiation’s is (R = Rydberg’s constant)
(1)
(2)
(3)
(4)
If the energy of a hydrogen atom in nth orbit is , then energy in the nth orbit of a singly ionized helium atom will be
(1) 4
(2) /4
(3) 2
(4) /2
The ground state energy of hydrogen atom is – 13.6 eV. What is the potential energy of the electron in this state
1. 0 eV
2. – 27.2 eV
3. 1 eV
4. 2 eV
As the electron in Bohr orbit of Hydrogen atom passes from state n = 2 to n = 1 , the kinetic energy K and potential energy U change as
(1) K two-fold, U four-fold
(2) K four-fold, U two-fold
(3) K four-fold, U also four-fold
(4) K two-fold, U also two-fold
The magnetic moment of a revolving electron around the nucleus varies with principal quantum number n as
(1)
(2)
(3)
(4)
Bohr's atom model assumes
(1) The nucleus is of infinite mass and is at rest
(2) Electrons in a quantized orbit will not radiate energy
(3) Mass of electron remains constant
(4) All the above conditions
The ratio of the speed of the electrons in the ground state of hydrogen to the speed of light in vacuum is
1. 1/2 2. 2/137
3. 1/137 4. 1/237
1. | \(E_0=-27.2 ~\text{eV};~r_0={a}_0 / 2\) |
2. | \(E_0=-27.2 ~\text{eV}; ~r_0={a}_0\) |
3. | \(E_0=-13.6~\text{eV} ; ~r_0={a}_0 / 2\) |
4. | \(E_0=-13.6 ~\text{eV}; ~r_0={a}_0\) |
A double charged lithium atom is equivalent to hydrogen whose atomic number is 3. The wavelength of required radiation for exciting electron from first to third Bohr orbit in will be (Ionisation energy of hydrogen atom is 13.6eV)
(a) 182.51 Å (b) 177.17 Å
(c) 142.25 Å (d) 113.74 Å
The ionisation potential of H-atom is 13.6 V. When it is excited from ground state by monochromatic radiations of , the number of emission lines will be (according to Bohr’s theory)
(1) 10
(2) 8
(3) 6
(4) 4