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Original Articles

Formation of two centre three electron bond by hydroxyl radical induced reaction of thiocoumarin: evidence from experimental and theoretical studies

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Pages 629-640 | Received 08 Jan 2019, Accepted 03 May 2019, Published online: 27 May 2019
 

Abstract

Radiation chemical studies of thioesculetin (1), a thioketone derivative of coumarin, were performed by both pulse radiolysis technique and DFT calculations. Hydroxyl (OH) radical reaction with 1 resulted transients absorbing at 320, 360 and 500 nm. To identify the nature of the transients, the reaction was studied with specific one-electron oxidant (N3) radical, where 360 nm band was absent. The transient absorption at 500 nm was concentration-dependent. The overall impression for OH radical reaction was that the transient absorbing at 320, 360 and 500 nm was due to sulphur centred monomer radical, hydroxysulfuranyl and dimer radical of 1 respectively. The equilibrium constant between the monomer to dimer radical was 3.75 × 104 M−1. From the transients’ redox nature, it was observed that 57 and 24% of OH radical yielded to oxidising and reducing products respectively. Further, the product analysis by HPLC suggested that the dimer radical disproportionate to esculetin and thioesculetin. DFT energy calculation for all the possible transients revealed that dimer radical has the lowest energy. The HOMO of 1 and its monomer radical suggested that the electron density was localised on the sulphur atom. The bond length between the two sulphur atoms in dimer radical was 2.88 Å which was less than the van der Waals distance. Bond order between the two sulphur atoms was 0.55, suggesting that the bond was two centre three electron (2c–3e). From TD-DFT calculation, the electronic transition of dimer radical was at 479 nm which was in close agreement with the experimental value. The nature of the electronic transition was σ → σ* from a 2c − 3e bond.

Acknowledgements

RGS thanks to Department of Atomic Energy, Government of India for providing fellowship under BARC-SPPU Collaborative Research programme. The authors have valuable discussion with Dr Beena G. Singh, BARC during preparation of the manuscript. The authors are also thankful to head RPCD, BARC and head Chemistry Department, SPPU for their constant encouragement and support.

Disclosure statement

The authors report that they have no conflicts of interest. The authors alone are responsible for the content and writing of the paper.

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