The ratio of `(E_(2) - E_(1))` to `(E_(4) - E_(3))` for `He^(+)` ion is approximately equal to (where `E_(n)` is the energy of nth orbit ):

E_(n) = total energy , l_(n) angular momentum K_(n) = K.E., V_(n) = P.E., T_(n) = time period , r_(n)= radius of nth orbit

The nuclei inbolbed in the nuclear reaction A_(1)+A_(2) rarrA_(3)+A_(4) have the binding energies E_(1),E_(2),E_(3) , and E_(4) . Find the energy of this reaction.

Tow cells of emf E_(1) and E_(2) ( E_(1) gt E_(2)) are connected individually to a potentiometer and their corresponding balancing length are 625 cm and 500 cm, then the ratio (E_(1))/(E_(2)) is .

Two electrons in two hydrogen - like atoms A and B have their total energies E_(A) and E_(B) in the ratio E_(A):E_(B)= 1 : 2 . Their potential energies U_(A) and U_(B) are in the ratio U_(A): U_(B)= 1 : 2 . If lambda_(A) and lambda_(B) are their de-Broglie wavelengths, then lambda_(A) : lambda_(B) is

A molecule may be represented by three structures having energies E_(1) , E_(2) " and " E_(3) , respectively . The energies of theses structures follow the order E_(3) lt E_(2) lt E_(1) , respectively . If the experimental bond energy of the molecule is E_(0) , their resonance energy is

The energy of e^(-) in first orbit of He^(+) is -871.6 xx 10^(-20) J . The energy of e^(-) in first orbit of H is :

A molecule may be represented by three structures having energies E_(1), E_(2) and E_(3) , respetively. The energies of these structures follow the order E_(2)ltE_(2)ltE_(1) , respectively. If the experimantal bond energy of the molecule is E_(0) , the resonance energy is :