Ionization energy comparison

Question

I'm a bit confused about this part since it doesn't specifically mention it in my book as far as I've read.

But let's say if I have to compare the ionization energy of the hydrogen atom to the ionization energy of Be$^{3+}$, I know that the ionization energy of the hydrogen atom is 13,6 eV and for Be$^{3+}$ it's about 218 eV, which in turn makes it about 16 times greater than the ionization energy for the hydrogen atom. Now here lies my confusion, what is meant by "The ionization energy is the energy difference between the $n→∞$ level energy and the $n =1$ level energy."

Where does "the n→∞ level energy" come from exactly?

Answer 1

An electron that has been separated completely from 'its' nucleus is said to be at infinite distance from that nucleus, because at that distance the Coulombic potential $V(r)$ is zero (formula for a hydrogenic atom):

$$V(r)=-\frac{Ze^2}{4\pi \epsilon_0 r}\implies V(r)\to 0\text{ for }r\to +\infty$$

For hydrogen the energy spectrum is given by:

$$E(n)=\frac{E_1}{n^2}$$

Where $n$ is the principal quantum number ($=1,2,3,...$) and $E_1=-13.6\ \mathrm{eV}$.

Here too: $$n\to+\infty \implies E(+\infty)\to0$$

For an infinitely high quantum number the electron's energy is zero.

So the ionisation energy is for hydrogenic atoms (in the ground state i.e. $n=1$) is:

$$\Delta E=E(+\infty)-E_1=-E_1$$

For actual hydrogen that is $-(-13.6\ \mathrm{eV})=+13.6\ \mathrm{eV}$.

For $\mathrm{Be}^{3+}$ that ionisation energy is much higher due to $E_1$ being much more negative than for $H$.