The journal of chemical education can be a fertile source of ideas for undergraduate student experiments. Take this procedure for asymmetric epoxidation of an alkene.[1] When I first spotted it, I thought not only would it be interesting to do in the lab, but could be extended by incorporating some modern computational aspects as well.
Oxygen atom transfer from this chiral dioxirane produces a specific enantiomer of the chiral epoxide in often high enantiomeric excess. For each alkene, there are up to eight possible transition states, arising from the following permutations:
In fact, using the standard ωB97XD/6-311G(d,p)/SCRF=solvent method used on this blog, locating each transition state for any specific alkene can take about 24 hours, and hence doing all eight can take a week or more per alkene. We have groups of around 20 students doing this experiment, and so it was not practical in terms of computing resources to get them all to individually find these transition states. Instead, we give the students access to groups of eight pre-run calculations[2] for four different alkenes and invited them to perform various tasks for their selected alkene. These include:
There are more tasks the students have to perform, and a full description will appear in an article I am writing.
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Hi Henry,
I noticed you have only posted transition states in which the catalyst features an anomeric affect (at least for the stilbene reaction), as well as one twist-boat transition state. Have you performed calculations on the other chair conformer?
Thanks,
The catalyst is derived from the crystal structure, where the anomeric effects manifest. But of course the two five rings can buckle either way, turning an 8-transition state problem into one of 32-conformations (or 64 for the two chair possibilities). Each transition state is initially optimised by fixing the three cleaving/forming bond lengths (O-O, C-O and C-O) and letting the system minimise the energy. Whilst this does not explore the conformations of the 5-rings, many possibilities are not possible because of steric clashes, and it is doubtful that all conformational possibilities manifest as locatable transition states.
If you do find a transition state with a lower energy, please let us know! Crowd-sourcing the stochastic process of exploring conformational space may be a good way of doing this!