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Aromatic and antiaromatic ring currents in a molecular nanoring

Abstract

Aromatic and antiaromatic molecules—which have delocalized circuits of [4n + 2] or [4n] electrons, respectively—exhibit ring currents around their perimeters1,2,3,4. The direction of the ring current in an aromatic molecule is such as to generate a magnetic field that opposes the external field inside the ring (a ‘diatropic’ current), while the ring current in an antiaromatic molecule flows in the reverse direction (‘paratropic’)5. Similar persistent currents occur in metal or semiconductor rings, when the phase coherence of the electronic wavefunction is preserved around the ring6,7. Persistent currents in non-molecular rings switch direction as a function of the magnetic flux passing through the ring, so that they can be changed from diatropic (‘aromatic’) to paratropic (‘antiaromatic’) simply by changing the external magnetic field. As in molecular systems, the direction of the persistent current also depends on the number of electrons8. The relationship between ring currents in molecular and non-molecular rings is poorly understood, partly because they are studied in different size regimes: the largest aromatic molecules have diameters of about one nanometre, whereas persistent currents are observed in microfabricated rings with diameters of 20–1,000 nanometres. Understanding the connection between aromaticity and quantum-coherence effects in mesoscopic rings provides a motivation for investigating ring currents in molecules of an intermediate size9. Here we show, using nuclear magnetic resonance spectroscopy and density functional theory, that a six-porphyrin nanoring template complex, with a diameter of 2.4 nanometres, is antiaromatic in its 4+ oxidation state (80 π electrons) and aromatic in its 6+ oxidation state (78 π electrons). The antiaromatic state has a huge paramagnetic susceptibility, despite having no unpaired electrons. This work demonstrates that a global ring current can be promoted in a macrocycle by adjusting its oxidation state to suppress the local ring currents of its components.The discovery of ring currents around a molecule with a circumference of 7.5 nanometres, at room temperature, shows that quantum coherence can persist in surprisingly large molecular frameworks.

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Figure 1: Molecular structures of the butadiyne-linked porphyrin oligomers used in this study. l-PN, c-PN and c-P6·T6.
Figure 2: Computational data supporting aromaticity and antiaromaticity.
Figure 3: Square-wave voltammetry of c-P6·T6.
Figure 4: NMR spectra of neutral and oxidised c-P6·T6.

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Acknowledgements

We thank the ERC (grant 320969), the EPSRC and the John Templeton Foundation for support, B. Odell for help with NMR spectroscopy and the Oxford Advanced Research Computing (ARC) centre for the high-performance computing provision (http://dx.doi.org/10.5281/zenodo.22558). M.D.P. thanks Exeter College, Oxford, for further support.

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M.D.P. synthesized the compounds, performed the calculations, collected and analysed the spectroscopic data. T.D.W.C. assisted with NMR data collection and interpretation. H.L.A. devised the project. M.D.P. and H.L.A. wrote the paper. All authors discussed the results and edited the manuscript.

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Correspondence to Harry L. Anderson.

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The authors declare no competing financial interests.

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Nature thanks M. Bröring and the other anonymous reviewer(s) for their contribution to the peer review of this work.

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This file contains Supplementary Tables 1-5 and Supplementary Figures 1-27. This file was updated on 11 January 2017 to correct the DOI number. (PDF 5478 kb)

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Peeks, M., Claridge, T. & Anderson, H. Aromatic and antiaromatic ring currents in a molecular nanoring. Nature 541, 200–203 (2017). https://doi.org/10.1038/nature20798

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