The number of repositories which accept research data across a wide spectrum of disciplines is on the up. Here I report the results of conducting an experiment in which chemical modelling data was deposited in six such repositories and comparing the richness of the metadata describing the essential properties of the six depositions.
A comparison of descriptive metadata across different data repositories.
September 28th, 2021HPC Access and Metadata Portal (CHAMP).
September 13th, 2021You might have noticed if you have read any of my posts here is that many of them have been accompanied since 2006 by supporting calculations, normally based on density functional theory (DFT) and these calculations are accompanied by a persistent identifier pointer‡ to a data repository publication. I have hitherto not gone into the detail here of the infrastructures required to do this sort of thing, but recently one of the two components has been updated to V2, after being at V1 for some fourteen years[1] and this provides a timely opportunity to describe the system a little more.
References
- M.J. Harvey, N.J. Mason, and H.S. Rzepa, "Digital Data Repositories in Chemistry and Their Integration with Journals and Electronic Notebooks", Journal of Chemical Information and Modeling, vol. 54, pp. 2627-2635, 2014. https://doi.org/10.1021/ci500302p
More record breakers for the anomeric effect involving C-N bonds.
September 4th, 2021An earlier post investigated large anomeric effects involving two oxygen atoms attached to a common carbon atom.
Tetra-isopropylmethane and tetra-t-butylmethane.
August 17th, 2021The homologous hydrocarbon series R4C is known for R=Me as neopentane and for R=Et as 3,3-diethylpentane. The next homologue, R=iPr bis(3,3-isopropyl)-2,4-dimethylpentane is also a known molecule[1] for which a crystal structure has been reported (DOI: https://doi.org/10.5517/cc4wvnh). The final member of the series, R= tbutyl is unknown. Here I have a look at some properties of the last two of these highly hindered hydrocarbons.
References
- S.I. Kozhushkov, R.R. Kostikov, A.P. Molchanov, R. Boese, J. Benet-Buchholz, P.R. Schreiner, C. Rinderspacher, I. Ghiviriga, and A. de Meijere, "Tetracyclopropylmethane: A Unique Hydrocarbon with S4 Symmetry", Angewandte Chemie International Edition, vol. 40, pp. 180-183, 2001. https://doi.org/10.1002/1521-3773(20010105)40:1<180::aid-anie180>3.0.co;2-k
Sterically stabilized cyclopropenylidenes. An example of Octopus publishing?
August 15th, 2021Whilst I was discussing the future of scientific publication in the last post, a debate was happening behind the scenes regarding the small molecule cyclopropenylidene. This is the smallest known molecule displaying π-aromaticity, but its high reactivity means that it is unlikely to be isolated in the condensed phase. A question in the discussion asked if substituting it with a large sterically hindering group such as R=Et3C might help prevent its dimerisation and hence allow for isolation of the monomer so that its properties can be studied.
Octopus publishing: dis-assembling the research article into eight components.
August 13th, 2021In 2011, I suggested that the standard monolith that is the conventional scientific article could be broken down into two separate, but interlinked components, being the story or narrative of the article and the data on which the story is based. Later in 2018 the bibliography in the form of open citations were added as a distinct third component.[1] Here I discuss an approach that has taken this even further, breaking the article down into as many as eight components and described as “Octopus publishing” for obvious reasons. These are;
References
- D. Shotton, "Funders should mandate open citations", Nature, vol. 553, pp. 129-129, 2018. https://doi.org/10.1038/d41586-018-00104-7
Another very large anomeric effect – with a twist.
July 22nd, 2021In the earlier post on the topic of anomeric effects, I identified a number of outliers associated with large differences in the lengths of two carbon-oxygen bonds sharing a common carbon atom.
Dimerisation of cyclopropenylidene: what are the correct “curly arrows” for this process?
July 21st, 2021In another post, a discussion arose about whether it might be possible to trap cyclopropenylidene to form a small molecule with a large dipole moment. Doing so assumes that cyclopropenylidene has a sufficiently long lifetime to so react, before it does so with itself to e.g. dimerise. That dimerisation has an energy profile shown below, with a free energy of activation of 14.4 kcal/mol, so a facile reaction that will indeed compete with reaction with Ph-I+-CC–. 
Molecules with very large dipole moments: cyclopropenium acetylide
July 11th, 2021Occasionally, someone comments about an old post here, asking a question. Such was the case here, when a question about the dipole moment of cyclopropenylidene arose. It turned out to be 3.5D, but this question sparked a thought about the related molecule below.
Two record breakers for the anomeric effect; one real, the other not.
July 1st, 2021The classic anomeric effect operates across a carbon atom attached to oxygens. One (of the two) lone pairs on the oxygen can donate into the σ* orbital of the C-O of the other oxygen (e.g. the red arrows) tending to weaken that bond whilst strengthening the donor oxygen C-O bond. Vice versa means e.g. the blue arrows weakening the other C-O bond. This effect tends to increase charge separation and the question then arises: how large can this effect get? To try to find out, we are going to do some crystal structure mining in this post! 