This Learning Object came to being sort of (In-)organically on the first day of my sophomore level intro to inorganic course. As I always do, I started the course with the IC Top 10 First Day Activity. (https://www.ionicviper.org/classactivity/ic-top-10-first-day-activity).  One of the pieces of that In class activity asks students- novices at Inorganic Chemistry- to sort the articles from the Most Read Articles from Inorganic Chemistry into bins of the various subdisciplines of Inorganic Chemistry.  As the discussion unfolded, I just sort of started spontaneously drawing a Venn Diagram on the board.  

I think Venn diagrams are an excellent logic tool, one that is too little applied these days for anything other than internet memes.  This is a nice little add-on activity to the first day.
 

Your Venn diagram will likely look different from mine.  You're right.

This is a flipped classroom module that covers the concepts of quantum numbers, and radial and angular nodes. This activity is designed to be done at the beginning of the typical first quarter/first semester general chemistry course (for an atoms first approach; if instructors use a traditional course structure this unit is likely done towards the middle/end of the first quarter/semester). Students will be expected to have learned the following concepts prior to completing this activity:

a) quantization of energy in the atom and the Bohr model of the atom;

b) how the wave/particle duality of electrons was described by de Broglie;

c) how the wave/particle duality of electrons was used by Schrodinger to develop the quantum mechanical model of the atom;

d) how radial probability distribution was used to generate the idea of atomic orbitals, and orbital probability surfaces.

This is a flipped classroom activity intended for use in a first semester general chemistry course. Students are expected to have prior knowledge in determining the molar mass of compounds, how to carry out mole/gram conversions, and how to write balanced chemical reactions. The activity includes: 1) pre-lecture learning videos that guide students through carrying out basic stoichiometric calculations, determining the limiting reactant, and determining the percent yield of a reaction; 2) a pre-lecture interactive tutorial that helps students learn the concept of limiting reactant; 3) pre-lecture quiz questions; and 4) an in-class activity that requires students to apply their knowledge of stoichiometry and limiting reactant in the real-world application of converting coal to liquid fuel.