On the resilience of magic number theory for conductance ratios of aromatic molecules

If simple guidelines could be established for understanding how quantum interference (QI) can be exploited to control the flow of electricity through single molecules, then new functional molecules, which exploit room-temperature QI could be rapidly identified and subsequently screened. Recently it...

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Veröffentlicht in:Scientific reports 2019-03, Vol.9 (1), p.3478-3478, Article 3478
Hauptverfasser: Ulčakar, Lara, Rejec, Tomaž, Kokalj, Jure, Sangtarash, Sara, Sadeghi, Hatef, Ramšak, Anton, Jefferson, John H., Lambert, Colin J.
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Sprache:eng
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Zusammenfassung:If simple guidelines could be established for understanding how quantum interference (QI) can be exploited to control the flow of electricity through single molecules, then new functional molecules, which exploit room-temperature QI could be rapidly identified and subsequently screened. Recently it was demonstrated that conductance ratios of molecules with aromatic cores, with different connectivities to electrodes, can be predicted using a simple and easy-to-use “magic number theory.” In contrast with counting rules and “curly-arrow” descriptions of destructive QI, magic number theory captures the many forms of constructive QI, which can occur in molecular cores. Here we address the question of how conductance ratios are affected by electron-electron interactions. We find that due to cancellations of opposing trends, when Coulomb interactions and screening due to electrodes are switched on, conductance ratios are rather resilient. Consequently, qualitative trends in conductance ratios of molecules with extended pi systems can be predicted using simple ‘non-interacting’ magic number tables, without the need for large-scale computations. On the other hand, for certain connectivities, deviations from non-interacting conductance ratios can be significant and therefore such connectivities are of interest for probing the interplay between Coulomb interactions, connectivity and QI in single-molecule electron transport.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-019-39937-1