In its ground state the electron is in the n= 1 energy level and it is completely removed from the atom when it is ionized.

These three rules/principles are mentioned on the syllabus but do not need full explanations. Essentially Hund's rule states that electrons fill orbitals singly before pairing up and Pauli's exclusion principles limits the number of electrons in each orbital to two, each having opposite spins. The aufbau principle states that lower energy levels and sub-levels are filled first.

Lines are produced in the emission spectra when electrons emit photons as they fall from higher to lower energy levels. The visible region is due to electrons falling from higher levels to the n=2 level. 

Each electron is defined by four different quantum numbers. The principle quantum number n describes the main energy levels.

There are three sub-levels, 3s, 3p and 3d. The s sub-level has 1 orbital, the p sub-level 3 orbitals and the d sub-level 5 orbitals giving a total of 9. 

Bromine (Z = 35) has 35 electrons. [Ar] has 18 electrons, two electrons in the 4s, ten in the 3d and the remaining five in the 4p sub-level.

Electrons pair up with opposite spins in full orbitals and occupy degenerate (equal energy) orbitals in the same sub-level singly first, all spinning the same way, before pairing up (Hund's rule).

Normally the 4s fills completely before the d sub-level fills but Cr and Cu are exceptions.

The three 2p orbitals are of equal energy lying along the three mutually orthogonal axes.

The electron configuration of Fe (Z = 26) is [Ar]4s²3d⁶. When it loses 3 electrons to form Fe³⁺ it loses both 4s electrons and one of the 3d electrons so the electron configuration of Fe³⁺ is [Ar]3d⁵. The five d orbitals will each contain one electron, all of them spinning in the same direction according to Hund's rule.