September 3rd, 2025
In the previous post[1] I mooted the possibility that a high energy form of the dimer of nitric oxide 1 might nonetheless be able to be detected using suitable traps (such as hydrogenation or cycloaddition). However, an interesting alternative is that this species could be trapped by nitric oxide itself. According to [2] in an article entitled “Decomposition of nitric oxide at elevated pressures” the rate of this termolecular reaction 3NO → N2O + NO2 are said to obey third order kinetics. One plausible mechanism for this process is shown below.
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References
- H. Rzepa, "Hydrogenating the even more mysterious N≡N triple bond in a nitric oxide dimer.", 2025. https://doi.org/10.59350/rzepa.29626
- T. Melia, "Decomposition of nitric oxide at elevated pressures", Journal of Inorganic and Nuclear Chemistry, vol. 27, pp. 95-98, 1965. https://doi.org/10.1016/0022-1902(65)80196-8
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August 25th, 2025
Previously[1] I looked at some of the properties of the mysterious dimer of nitric oxide 1 – not the known weak dimer but a higher energy form with a “triple” N≡N bond. This valence bond isomer of the weak dimer was some 24 kcal/mol higher in free energy than the two nitric oxide molecules it would be formed from. An energy decomposition analysis (NEDA) of 1 revealed an interaction energy[2] of +4.5 kcal/mol for the two radical fragments, compared to eg -27 kcal/mol for the equivalent analysis of the N=N double bond in nitrosobenzene dimer[3] So here I take a look at another property of N≡N bonds via their hydrogenation energy (Scheme), mindful that the dinitrogen molecule requires forcing conditions to hydrogenate, in part because of the unfavourable entropy terms (See Wiki and also here‡ for a calculation of ΔG298).
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References
- H. Rzepa, "The even more mysterious N≡N triple bond in a nitric oxide dimer.", 2025. https://doi.org/10.59350/rzepa.29429
- H. Rzepa, "N2O2 as strong dimer? bent NEDA 0 1 0 2 0 -2 Total Interaction (E) : 4.520 Wiberg NN bond index 1.0072 NN stretch 2604 cm-1", 2025. https://doi.org/10.14469/hpc/15468
- H. Rzepa, "Nitrosobenzene dimer NEDA=2, 0,1 0,1 0,1 Total Interaction (E) : -27.564", 2025. https://doi.org/10.14469/hpc/15444
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August 19th, 2025
I started adding citations to my blog posts around 2012 using the Kcite plugin.‡ Rogue Scholar is a service that monitors registered blog sources and adds all sorts of value to the original post, including identifying such citations and creating a list of them.
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August 19th, 2025
Two years ago, I posted on the topic “Internet Archeology: reviving a 2001 article published in the Internet Journal of Chemistry (IJC)”.[1] The IJC had been founded in 1998,[2] in part at least to “re-invent” the scholarly journal by elevating research data to being a more integrated part of the overall article, rather than as the previously conventional addendum of SI (Supporting Information)‡. IJC was in one sense following on from an earlier such project dating from 1995[3] by taking it to the next level. Sadly, the pioneering IJC journal had gone off-line in 2004 and the content for around 100 articles was thought lost. It happened that I still retained the original source and associated data for one article of mine and my post[1] described how I managed to get it back into more or less full working order. Now Egon Willighagen[4] has cleverly found a way of rescuing many more of these lost articles, thanks to various Web-based infrastructures: Read the rest of this entry »
References
- H. Rzepa, "Internet Archeology: reviving a 2001 article published in the Internet Journal of Chemistry.", 2024. https://doi.org/10.59350/xqerh-wam97
- S.M. Bachrach, and S.R. Heller, "The<i>Internet Journal of Chemistry:</i>A Case Study of an Electronic Chemistry Journal", Serials Review, vol. 26, pp. 3-14, 2000. https://doi.org/10.1080/00987913.2000.10764578
- D. James, B.J. Whitaker, C. Hildyard, H.S. Rzepa, O. Casher, J.M. Goodman, D. Riddick, and P. Murray‐Rust, "The case for content integrity in electronic chemistry journals: The CLIC project", New Review of Information Networking, vol. 1, pp. 61-69, 1995. https://doi.org/10.1080/13614579509516846
- E. Willighagen, "The Internet Journal of Chemistry", 2025. https://doi.org/10.59350/2ss5b-jpr33
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August 18th, 2025
Previously, I pondered about the strange N=N double bond in nitrosobenzene dimer[1] as a follow up to commenting on the curly arrow mechanism of the dimerisation.[2] By the same curly arrow method, one can produce the below, showing how the simpler nitric oxide radical could potentially dimerise to a species with a N≡N triple bond!† This involves a total of six electrons entering the N-N region, and hence raises the question of whether these all move in a single concerted/synchronous bond forming reaction, or whether they might go in (asynchronous) stages. Here are some calculations[3]) which might shed some light on this aspect.
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References
- H. Rzepa, "The mysterious N=N double bond in nitrosobenzene dimer.", 2025. https://doi.org/10.59350/rzepa.29383
- H. Rzepa, "Mechanism of the dimerisation of Nitrosobenzene.", 2025. https://doi.org/10.59350/rzepa.28849
- H. Rzepa, "N2O2 as strong dimer TS as biradical cis, G = -259.785500", 2025. https://doi.org/10.14469/hpc/15483
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August 13th, 2025
In the previous post,[1] I introduced the N=N double bond in nitrosobenzene dimer, arguing that even though it was a formal double bond, its bond dissociation energy made it nonetheless a very weak double bond! This was backed up by a technique known as energy decomposition analysis or EDA. Here I use a variant of this method known as NEDA to look at some other strained alkenes, including the famously non-existent tetra t-Butyl ethene.
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References
- H. Rzepa, "The mysterious N=N double bond in nitrosobenzene dimer.", 2025. https://doi.org/10.59350/rzepa.29383
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August 11th, 2025
In an earlier blog, I discussed[1] the curly arrows associated with the known dimerisation of nitrosobenzene, and how the N=N double bond (shown in red below) forms in a single concerted process.
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References
- H. Rzepa, "Mechanism of the dimerisation of Nitrosobenzene.", 2025. https://doi.org/10.59350/rzepa.28849
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July 22nd, 2025
In the previous post[1] I followed up on an article published on the theme “Physical Organic Chemistry: Never Out of Style“.[2] Paul Rablen presented the case that the amount of o (ortho) product in electrophilic substitution of a phenyl ring bearing an EWG (electron withdrawing group) is often large enough to merit changing the long held rule-of-thumb for EWGs from being just meta directors into being ortho and meta-directors, with a preference for meta. I showed how Paul’s elegant insight could be complemented by an NBO7 analysis of the donor-acceptor interactions in the σ-complex formed by protonating the phenyl ring bearing the EWG. Both the o– and m– isomers showed similar NBO orbital patterns and associated E(2) donor/acceptor interaction energies and also matched the observation that the proportion of meta is modestly greater than ortho substitution (steric effects not modelled). These interactions were both very different from those calculated for the para isomer.
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References
- H. Rzepa, "“Typical Electron-Withdrawing Groups Are o, m-Directors Rather than m-Directors in Electrophilic Aromatic Substitution”", 2025. https://doi.org/10.59350/rzepa.28993
- P.R. Rablen, "Typical Electron-Withdrawing Groups Are <i>ortho</i>, <i>meta</i>-Directors Rather than <i>meta</i>-Directors in Electrophilic Aromatic Substitution", The Journal of Organic Chemistry, vol. 90, pp. 6090-6093, 2025. https://doi.org/10.1021/acs.joc.5c00426
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July 17th, 2025
The title of this post comes from an article published in a special virtual issue on the theme “Physical Organic Chemistry: Never Out of Style“[1] There, Paul Rablen presents the case that the amount of o (ortho) product in electrophilic substitution of a phenyl ring bearing an EWG (electron withdrawing group) is often large enough to merit changing the long held rule-of-thumb for EWGs from being just meta directors into these substituents are best understood as ortho, meta-directors, with a preference for meta. I cannot help but add here a citation[2] to the earliest publication I can find showing tables of both o,p and m-directing groups and dating from 1887, so this rule is 138 years old (at least).
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References
- P.R. Rablen, "Typical Electron-Withdrawing Groups Are <i>ortho</i>, <i>meta</i>-Directors Rather than <i>meta</i>-Directors in Electrophilic Aromatic Substitution", The Journal of Organic Chemistry, vol. 90, pp. 6090-6093, 2025. https://doi.org/10.1021/acs.joc.5c00426
- H.E. Armstrong, "XXVIII.—An explanation of the laws which govern substitution in the case of benzenoid compounds", J. Chem. Soc., Trans., vol. 51, pp. 258-268, 1887. https://doi.org/10.1039/ct8875100258
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June 25th, 2025
This are just a few insights I have got from some of the talks I attended. As usual, this does not represent a report on the WATOC congress itself, but simply some aspects that caught my personal eye. Read the rest of this entry »
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