Equations have been applied to the above problems for hydrogen atom. Can these equations be applied to calculate r, E, v, etc for `He^(+) and Li^(2+)` ions?

How can Nernst equation be applied in calculating the equilibrium constant for any cell reaction ?

(a) Find the radius of Li(++) ions in its grounds state assuming Bohr's model to be valid. (b) Find the maximum angular speed of the electron of a hydrogen atom in a stationary orbit. (c ) Average lifetime of a H atom excited to n=2 state is 10^(-8) sec. Find the number of revolutions made by the electron on the average before it jumps to the ground state. (d) Calculate the magnetic dipole moment corresponding to the motion of the electron in the ground state of a hydrogen atom. (e) Using the known values for hydrogen atom, calculate : (i) radius of third orbit for Li^(+2) (ii) speed of electron in fourth orbit for He^(+)

Statement-1 : Bernoullis equation is based on energy conservation. Statement-2 : Bernoullis equation can only be applied if the flow is streamlined. Statement-3 : Bernoullies equation can be applied evern if the flow is not streamlined as total energy is always conserved.

The radius of first Bohr orbit of hydrogen atom is 0.529 Å . Calculate the radii of (i) the third orbit of He^+ ion and (ii) the second orbit of Li^(2+) ion.

Consider the previous problem , let the outer shell have the charge - 4 q . As in the above problem , the inner shell has the charge + 2q . Calculate the electric field in terms of q and the distance r from the common center of the two shells for The graph of the radial component of E as function of r will be

Consider the previous problem , let the outer shell have the charge - 4 q . As in the above problem , the inner shell has the charge + 2q . Calculate the electric field in terms of q and the distance r from the common center of the two shells for r lt a