The number of orbitals in a sublevel is determined by the magnetic quantum number, which can have integer values between -l and +l, where l is the azimuthal quantum number associated with each sublevel. For the p sublevel, l=1, which gives magnetic quantum numbers of -1, 0, and 1. These three values correspond to the three p orbitals: px, py, and pz. For the d sublevel, l=2, yielding magnetic quantum numbers of -2, -1, 0, 1, and 2, corresponding to the five different d orbitals. The shape and orientation of these orbitals in space are distinct due to these magnetic quantum numbers.

Yes, there are instances, particularly among transition metals, where electrons from the s sublevel are removed before the d electrons during ionisation. This phenomenon can be attributed to the relatively close energy levels of the s and d orbitals in these elements. For example, in the ionisation of chromium, the 4s electrons are removed before the 3d electrons. When the 4s and 3d orbitals are both occupied, the 4s electrons are actually at a slightly higher energy than the 3d electrons, making them easier to remove. This illustrates the complexity and nuances of electron configurations and ionisation in transition metals.

Using the noble gas core in condensed electron configurations offers a shorthand method to represent electron configurations without writing out all the electrons. Noble gases have a full set of electrons in their outermost energy level, which makes them stable. By starting with the electron configuration of the closest noble gas with fewer electrons than the atom in question, chemists can save time and provide a clear picture of the valence electrons, which are most pertinent in chemical reactions. It simplifies the representation and allows for a more direct focus on the outermost, and chemically significant, electrons of the atom.

The Pauli Exclusion Principle states that no two electrons in an atom can have the same set of four quantum numbers, meaning two electrons in the same orbital must have opposite spins. On the other hand, Hund's Rule states that electrons will occupy degenerate (equal energy) orbitals singly before pairing up. When determining electron configurations, these two principles work hand-in-hand. For instance, when filling the p orbitals, an electron will go into each of the three p orbitals (px, py, pz) with parallel spins before any pairing occurs, abiding by Hund's Rule. However, when electrons do pair up in an orbital, they must have opposite spins, which is dictated by the Pauli Exclusion Principle.

The naming convention for orbitals, especially the d orbitals, can indeed be a bit perplexing. The primary reason for this lag is historical and stems from the way the energy levels of these orbitals were first observed and categorised. The 4s orbital is actually lower in energy than the 3d orbitals when they're both empty. Thus, the 4s fills before the 3d. However, once the 4s orbital starts filling, its energy increases, making the 3d orbitals more stable in comparison. The 3d name simply signifies that these orbitals are associated with the third main energy level (n=3), even though they fill during the fourth period of the periodic table.