Author
Listed:
- Connor Fields
(University of Nottingham)
- Aleksandra Foerster
(University of Nottingham)
- Sadegh Ghaderzadeh
(University of Nottingham)
- Ilya Popov
(University of Nottingham)
- Bang Huynh
(University of Nottingham)
- Filipe Junqueira
(University of Nottingham)
- Tyler James
(University of Nottingham)
- Sofia Alonso Perez
(University of Nottingham)
- David A. Duncan
(University of Nottingham
Harwell Science & Innovation Campus)
- Tien-Lin Lee
(Harwell Science & Innovation Campus)
- Yitao Wang
(University of Nottingham)
- Sally Bloodworth
(University of Southampton)
- Gabriela Hoffman
(University of Southampton)
- Mark Walkey
(University of Southampton)
- Richard J. Whitby
(University of Southampton)
- Malcolm H. Levitt
(University of Southampton)
- Brian Kiraly
(University of Nottingham)
- James N. O’Shea
(University of Nottingham)
- Elena Besley
(University of Nottingham)
- Philip Moriarty
(University of Nottingham)
Abstract
Charge transfer is fundamentally dependent on the overlap of the orbitals comprising the transport pathway. This has key implications for molecular, nanoscale, and quantum technologies, for which delocalization (and decoherence) rates are essential figures of merit. Here, we apply the core hole clock technique—an energy-domain variant of ultrafast spectroscopy—to probe the delocalization of a photoexcited electron inside a closed molecular cage, namely the Ar 2p54s1 state of Ar@C60. Despite marginal frontier orbital mixing in the ground configuration, almost 80% of the excited state density is found outside the buckyball due to the formation of a markedly diffuse hybrid orbital. Far from isolating the intracage excitation, the surrounding fullerene is instead a remarkably efficient conduit for electron transfer: we measure characteristic delocalization times of 6.6 ± 0.3 fs and ≲ 500 attoseconds, respectively, for a 3D Ar@C60 film and a 2D monolayer on Ag(111).
Suggested Citation
Connor Fields & Aleksandra Foerster & Sadegh Ghaderzadeh & Ilya Popov & Bang Huynh & Filipe Junqueira & Tyler James & Sofia Alonso Perez & David A. Duncan & Tien-Lin Lee & Yitao Wang & Sally Bloodwort, 2025.
"Timing the escape of a photoexcited electron from a molecular cage,"
Nature Communications, Nature, vol. 16(1), pages 1-10, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-60260-z
DOI: 10.1038/s41467-025-60260-z
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