The ratio of `(E_2 - E_1) "to" (E_4 - E_3)` for the hydrogen atom is approximately equal to.

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 ):

In hydrogen and hydrogen-like atom , the ratio of E_(4 n) - E_(2 n) and E_(2 n) - E_(n) varies with atomic nimber z and principal quantum number n as

IF log_e3=1.0986 , then log_e(9.01) approximately is

The minimum kinetic energy of an electron,hydrogen ion,helium ion required for ionization of a hydrogen atom is E_(1) in case electron is colided with hydrogen atom. It is E_(2) if hydrogen ioniscollided and E_(3) when helium ioniscollided.Then:

The minimum kinetic energy required for ionization of a hydrogen atom is E_(1) in case electron is collided with hydrogen atom , it is E_(2) if the the hydrogen ion is collided and E_(1) when helium ion collided . Then.

If E_1:x^2/a^2+y^2/b^2=1 , agtb . E_2 is an ellipse which touches E_1 at the ends of major axis of E_1 and end of major axis of E_1 are the focii of E_2 and the eccentricity of both the ellipse are equal then find e

Of the three independent events E_1, E_2 and E_3, the probability that only E_1 occurs is alpha, only E_2 occurs is beta and only E_3 occurs is gamma. Let the probability p that none of events E_1, E_2 and E_3 occurs satisfy the equations (alpha-2beta), p=alphabeta and (beta-3gamma) p=2beta gamma. All the given probabilities are assumed to lie in the interval (0,1). Then,(probability of occurrence of E_1) / (probability of occurrence of E_3) is equal to

In the hydrogen atom, the energies corresponding to first, second and third orbits are given by E_1 = -13.6 eV, E_2 = -3.5eV, E_3 = -1.5 eV. If the atom emits a photon of energy 12.1 eV, in a transition, then the corresponding change in the angular momentum is given by