Archive for May, 2026

A breakthrough in Molecular Solar Thermal (MOST) energy storage – Dewar Pyrimidone.

Thursday, May 14th, 2026

MOST is a chemical method of converting photonic or light energy into storable thermal energy which can be released on demand. A recent breakthrough in such methods has been reported[1] in which a pyrimidone molecule is efficiently converted by 310nm light into the isomeric Dewar pyrimidone. This molecule is thermally stable, but when protonated, rapidly releases thermal (enthalpic) energy in converting down to protonated pyrimidone – the energy release is sufficiently rapid that it can boil water and reaching energy storage levels previously inaccessible to MOST systems. The basic chemistry is shown below – treatment with base makes it fully cyclic.

The chemical reactions are interesting. The light catalysed step is a pericyclic electrocyclic reaction, allowed by the Woodward-Hoffmann rules with stereochemical disrotation via suprafacial bond formation. The acid catalysed thermal reaction however, in order to conform to these rules, would nominally need to be an electrocycic ring opening with an antarafacial stereochemical component. This would require the bicyclic ring system to contain a trans rather than the cis bridgehead stereochemistry shown above.This reaction was first studied many years ago[2] when it was shown that the thermal ring opening of a cis Dewar isomer indeed has a high barrier, due to its “forbidden” character. This imparts one of the desirable characteristics of a MOST system, namely the ability to store the high energy compound if necessary for long periods of time. The key step in the above is recognising that protonating the bicyclic nitrogen of the Dewar form should significantly reduce the barrier to ring opening. Here to illustrate these two reactions, I show intrinsic reaction coordinates (IRCs) for both steps.

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References

  1. H.P.Q. Nguyen, A.J. Maertens, B.A. Baker, N.M. Wu, Z. Ye, Q. Zhou, Q. Qiu, N. Kaur, D.B. Berkinsky, K.E. Shulenberger, K.N. Houk, and G.G.D. Han, "Molecular solar thermal energy storage in Dewar pyrimidone beyond 1.6 megajoules per kilogram", Science, vol. 392, 2026. https://doi.org/10.1126/science.aec6413
  2. M.J.S. Dewar, G.P. Ford, and H.S. Rzepa, "Electrocyclic ring opening of 1α,4α- and 1α,4β-bicyclo[2.2.0]hexa-2,5-dienes (cis and trans Dewar benzenes): MNDO (modified neglect of diatomic overlap) semiempirical molecular orbital calculations", J. Chem. Soc., Chem. Commun., pp. 728-730, 1977. https://doi.org/10.1039/c39770000728

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Anomeric isomerism in cyclo-heptasulfur.

Wednesday, May 6th, 2026

A little while back, I wrote about anomeric-like effects in the sulfur ring S7.[1] I had started that exploration by retrieving the crystal structure from the ICSD (Inorganic crystal structure database) and then optimising these coordinates using a DFT method (MN15L/Def2-TZVPP to be precise). In demonstrating this effect to a student, I decided to create an initial guess for the molecule coordinates not from the crystal structure but by drawing and then minimising using a simple molecular mechanics force field – and only then subjecting it to DFT re-optimisation.[2] It turns out the result was quite surprising in one respect and so here I tell the rest of the story.

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References

  1. H. Rzepa, "Cyclo-Heptasulfur, S<sub>7</sub> – a classic anomeric effect discovered during a pub lunch!", 2025. https://doi.org/10.59350/rzepa.28407
  2. H. Rzepa, "Anomeric isomerism in cyclo-heptasulfur.", 2026. https://doi.org/10.14469/hpc/15924

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