Alas, I don't have a suggestion for you.  My knowledge of powder diffraction, while once larger, now would not fill the head of a goniometer pin...

But I did think of a way to boost the economy.  Somebody give me a good enough reason for buying a powder instrument, and I'll get one for HMC to teach the lab.

Adam

As a user of powder diffraction, I love this question!  The problem is where to start!  I don't think I can meet all of your criteria (particularly fix the economy), but I can help you put together something simple and (hopefully) effective.

At the very basic level, where you're only going to see the technique once (or maybe twice), there are two starting off points:

1. learn that powder data provides a "fingerprint" of a material 
2. learn how to do analysis of simple powder data
   

In which direction do you want to go?

I will add one more twist that could come out of either choice 1 or 2 that Barb mentions.  I like to use powder diffraction to introduce the concept of solid solutions in extended solids.  Students could look qualitatively at "fingerprint" patterns and see how they shift when you introduce various amounts of larger or smaller ions in an extended structure.  Or they could learn to fit the powder data to determine lattice parameters for the unit cell and track the solid solution behavior more quantitatively.  This kind of experiment makes a nice class project where each student makes a slightly different composition in the solid solution family.  I typically target a family of layered perovskite materials such as RbCa_2-xSr_xNb₃O₁₀, prepared by classic heat and beat solid state synthesis.  I have been meaning to pull this lab together and post it as a learning object (maybe once the semester is over).  There might be other systems that would also work and could illustrate an alternative materials synthesis approach.

Maggie beat me to the punchline on the type of experiments that I was most likely to suggest.  If you don't care so much about learning to analyze data, using XRD as a fingerprinting tool is great.  It's always fun to take a bunch of white powders and match them to a series of known possibilities.  While I've never done it, I've always wanted to set my student to synthesize some paint pigments in the same color family so they could see why a technqiue like powder xrd can be used to identify forgeries because of the changes in compounds used to get a particular color.

 If you want to do real data analysis, Maggie's suggestion on soid solutions is the way to go.  Another system (whose synthesis is written up in JCE, I think) are the tungsten bronzes, NaxWO3.  These can be grown from a melt by running a current through the solution.  The colors are absolutely beautify and you will see diffferences in the xrd data.  I'll have to take a look on the JCE search engine later.

One possibility that might appeal better to a molecular chemist would be (1) to do some isomorphous substitution (if there is enough difference in size of the metal ion, you should see a noticable change in the lattice parameters); (2) to look at coordination chemistry isomers (e.g. different inner and outer shell) which will have very different unit cells and hence powder patterns; or (3) to look at molecules that have several polymorphs.  There are plenty of organic examples of case 3; I wish I had organic suggestion on the latter.  What I think is so neat about these is that the polymorph produced during crystallization can have a profound effect on the activity of a drug.

The JCE reference for the tungsten bronze lab is:

Conroy, L. E. "The preparation and characterization of a sodium tungsten bronze." J. Chem. Educ. 1977, 54, 45-49.

 It's not a new paper, but I'd label it a as classic.  PXRD is discussed as a characterization technique in the paper.

If you'd like to update the chemistry a bit and talk about new applications by related materials, you can check out a paper from Shiv Halasyamani's group at University of Houston (Inorg. Chem. 2008, 47, 8511-8517).  While the synthesis in this paper doesn't meet your criterion, it would be a way to introduce neat properties of solid state materials.

this is for fun:

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Enjoy!  :-)