Rules for quantum numbers are confusing but not arbitrary.  They are based on wave mathmatics, and once laid out properly are symmetric and beautiful.  Within four animation-clicks of the first slide of this PowerPoint Presentation, this beauty will unfold.  I do not exaggerate to say, faculty members will be agape and students will say, "Why didn't you show us this before."  No other presentation shows in as elegant a way the relationship between 1)  n, l and m_l, 2) the ordering of orbitals in hydrogen-like atoms, and 3) the ordering of orbitals in the periodic table (along with the difficulty of assigning orbital filling in transition and f-block elements).  

Beauty is in every atom.  Let it loose.

In the primary literature, goemetry indices are being used quite often to describe four- and five-coordinate structures adopted by transition metal complexes. This slide deck, which is longer than the intended 5 slides, describes the three common geometry indices (tau4, tau4', and tau5) and provides example calculations for structures that are freely available in the Teaching Subset of the Cambridge Structural Database. (Students can access these structures in Mercury, which is freely available from the CCDC, or via a web request form for which the link is provided below.)

These five slides are intended to share a visual scaffolding that I developed to help my general chemistry students identify what calculations are needed to solve stoichiometry problems.

The visual scaffold involves writing the balanced equation and then under it drawing a table with two rows and enough columns so that there is one column under each reagent in the equation. The top row is labeled as "moles" and the bottom row is labeled as "measurable quantity". Students then write in any information about a specific reagent or product that was given and identify the quantity that the question is asking them to find. They then add a series of arrows to the table to generate a "map" of how to get from the information they are given to the information they need to find with each arrow representating a type of calculation that they have already seen and practiced. Vertical arrows represent a calculation between a measured quantity and a number of moles. Horizontal arrows in the top row represent calculations between moles of one substance and moles of another substance. Horziontal arrows in the "measured quantity" row are not allowed since those unit conversion factors are not readily available.