Soppose potential energy between electronand proton at seperation `r` is given by `U = klog r, where k` is a constant. For such a hypothetical hydrogen atom , calculate the radins of nth Bohr and its energy level

Assume a hypothetica hydrogen atom in which the potential energy between electron and proton at separation r is given by U = [k in r - (k/2)], where k is a constant. For such a hypothetical hydrogen atom, calcualete the radius of nth Bohr orbit and energy levels.

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.

Suppose the potential energy between electron and proton at a distance r is given by U= Ke l n(r )/(a) , where r lt a and k, e,a are positive constants. Use Bohr's theory to obtain the energy of nth energy level of such an atom.

Suppose the potential energy between electron and proton at a distance r is given buy -k e^(2)//3 r^(3) . Use Bohr's theory, determine energy levels of such a hypothetical atom.

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

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

In a hypothetical atom, potential energy between electron and proton at distance r is given by ((-ke^(2))/(4r^(2))) where k is a constant Suppose Bohr theory of atomic structrures is valid and n is principle quantum number, then total energy E is proportional to

Suppose the potential energy between electron and proton at a distance r is given by -(Ke^(2))/(3r^(2) .As per Bohr's quantization rule,the speed of electron in n th orbit of H-atom is

The potential energy of a two particle system separated by a distance r is given by U(r ) =A/r where A is a constant. Find to the radial force F_(r) , that each particle exerts on the other.

If potential energy between a proton and an electron is given by | U | = k e^(2)//2 R^(3) , where e is the charge of electron and R is the radius of atom , that radius of Bohr's orbit is given by (h = Plank's constant, k = constant)