A Hydrogen atom and `Li^(++)` ion are both in the second excited state. If `L_(H)` and `L_(Li)` are their respective angular momenta, and `E_(H)` and `E_(Li)` their respective energies, then:

A hydrogen atom and a Li^(2+) ion are both in the second excited state. If l_H and l_(Li) are their respective electronic angular momenta, and E_H and E_(Li) their respective energies, then (a) l_H gt l_(Li) and |E_H| gt |E_(Li)| (b) l_H = l_(Li) and |E_H| lt |E_(Li)| (C ) l_H = l_(Li) and |E_H| gt |E_(Li)| (d) l_H lt l_(Li) and |E_H| lt|E_(Li)|

A hydrogen atom and a Li^(2+) ion ae both in the second excited state . If l_H and l_(li) are their respective angular momentum in an orbit and E_H and E_(Li) are their respective enrgies, then :

A Hydrogen alon and Li^(++) ion are both in the second excired state . If l_(H) and l_(Li) are their respective energies, then

The moment of inertia of two freely rotating bodies A and B are l_(A) and l_(B) respectively. l_(A) gt l_(B) and their angular momenta are equal. If K_(A) and K_(B) are their kinetic energies,then

The ratio of energies of the H-atom, in its first to second excited state is

Consider atoms H, He^(+), Li^(++) in their ground states. If L_(1), L_(2) and L_(3) are magnitude of angular momentum of their electrons about the nucleus respectively then:

Calculate the energy of Li^(+2) atom for 2^(nd) excited state.

If energy of the electron in hydrogen atom in some excited state is -3.4e V then what will be its angular momentum

A moving H-atom makes a head on perfectly inelastic collision with a stationary Li^(++) ion. Just before collision, both - H and Li^(++) are in their first excited state. Immediately after collision H was found to be in ground state and Li^(++) was in its second excited state. Find the kinetic energy of H – atom before collision. No photon is emitted in the process. Assume that mass of Li^(++) is nearly 7 times the mass of H.

Find ratio of velocities of electrons in 2^(nd) excited state of Li^(+2) ion & 3^(rd) excited state of H-atom.