Students in a sophomore-level inorganic chemistry course read the paper "High-Pressure Synthesis and Characterization of the Alkali Diazenide Li₂N₂" prior to a class discussion, held during a conference session.  A link to the pdf file was posted to the course Moodle, and students were asked to complete the short list of discussion questions (attached below as a Word document) prior to coming to conference.  I also used the Jmol resource embedded in a course Moodle page to display the unit cell of the Li₂N₂ structure (the pdb file that I used as the input for Jmol is attached below.) On the Moodle page with the Jmol structure, I told students, “Sorry, I don't know how to make Jmol draw the boundaries of the unit cell!  To guide your eye, there are lithium atoms (in lavendar) at all 8 corners of the unit cell.”  This Jmol model was intended to help students answer questions 4 and 5 in the attached list of questions in addition to Figure 2 from the paper.

I used this learning object during the past two years at different times during my course.  In Spring 2012, the paper was assigned in week 4 of the semester, after covering periodic trends in atomic properties, ionic structures, unit cells, stoichiometries of extended structures, basic X-ray powder diffraction, and Lewis structures.  In Spring 2013, the paper was assigned in week 9 of the semester, after MO theory of diatomics was also covered in addition to the previous topics.  The attached discussion questions were from the Spring 2013 version.

During conference, we used the discussion questions as a guide to walk through the paper.  I explained to students how to access the Supporting Information for a paper and the varying utility of this information, depending on the article.  In this case, the Supporting Information is quite helpful, and we talked through key figures and tables in both the paper and in the Supporting Information.  We also discussed the synthesis, and I answered some questions on the characterization methods, explaining briefly what Rietveld refinement is and how the results in Table 1 and Figure 1 are correlated.  For more information on the Rietveld refinement method, see the Web Resource on Powder Diffraction Crystallography Instructional Materials.  Finally, we took the last 10 minutes of conference, and I made all the students get up and in small groups, draw the MO diagram and molecular orbital surfaces for (N₂)^2– on the white boards around the room.  I circulated and made comments and corrections to each group on their MO diagrams.  

I also used this paper for one student as part of our Junior Qualifying Exam in Inorganic Chemistry.  In this format, the student has 3 days to read the paper and learn about it before taking a 30 minute oral exam, which takes the form of a question-and-answer based discussion of the paper.  For the Junior Qual, we spent most of the time discussing the diffraction analysis of the material, molecular orbital theory of the diazenide ion, and a brief discussion of the properties of lithium diazenide.

Finally, although I have not done so yet, I intend to use this paper in my Advanced Inorganic Chemistry course where we cover the electronic band structure of extended solids in more detail. Our discussions in Advanced I-chem are based on Roald Hoffmann’s book, Solids and Surfaces: A Chemist’s View of Bonding in Extended Structures.  The details of the Li₂N₂ electronic band structure calculations provided in the Supporting Information for this paper are an excellent illustration of many of the key concepts presented in Hoffmann’s book.