The electric potential between a proton and as electron is given by `V= V_(0) ln (r )/(r_(0))` , where`r_(0)` is a constant . Assuming Bohr's model to be applicable , write variation of `r_(n)` with `n,n` being the principal quantum number ?

The electron in a hydrogen atom makes a transition n_(1) rarr n_(2) , where n_(1) and n_(2) are the principle quantum numbers of the two states. Assume the Bohr model to be valid. The time period of the electron in the initial state is eight times that in the final state. the possible values of n_(1) and n_(2) are

Suppose the potential energy between an electron and a proton at a distance r is given by Ke^(2)// 3 r^(3) . Application of Bohr's theory tohydrogen atom in this case showns that

According to Bohr's model of atom the orbit of an electron ...... [Where n is quantum number and Z = atomic number].

Suppose the potential energy between electron and proton at a distance r is given by (ke^(2))/(3r^(3)) . Use Bohr's theory to obtain energy of such a hypothetical atom.

The electron in a hydrogen atom makes a transition n_(1) rarr n_(2) where n_(1) and n_(2) are the principal qunatum numbers of the two states. Assume the Bohr model to be valid. The frequency of orbital motion of the electron in the initial state is 1//27 of that in the final state. The possible values of n_(1) and n_(2) are

Suppose an electron is attracted towards the origin by a force (k)/(r ) where k is a constant and r is the distance of the electron from the origin. By applying Bohr model to this system, the radius of the n^(th) orbital of the electron is found to be r_(n) and the kinetic energy of the electron to be T_(n) . Then which of the following is true?

An electric field converges at the origin whose magnitude is given by the expression E=100r N//C , where r is the distance measured from the origin.

Suppose drift velocity over the entire cross section of a wire is V (r) = V_(0) [ 1 - (r)/(R) ] . What is the current density at the surface of the wire ?

From the relation R = R_0A^(1//3) , where R_0 is a constant and A is the mass number of a nucleus, show that the nuclear matter density is nearly constant (i.e. independent of A).