Author
Listed:
- S. Jamali
(University of Utah)
- V. V. Mkhitaryan
(University of Utah)
- H. Malissa
(University of Utah)
- A. Nahlawi
(University of Utah)
- H. Popli
(University of Utah)
- T. Grünbaum
(Universität Regensburg)
- S. Bange
(Universität Regensburg)
- S. Milster
(Universität Regensburg)
- D. M. Stoltzfus
(The University of Queensland)
- A. E. Leung
(National Deuteration Facility, Australian Nuclear Science and Technology Organization (ANSTO)
European Spallation Source ERIC)
- T. A. Darwish
(National Deuteration Facility, Australian Nuclear Science and Technology Organization (ANSTO))
- P. L. Burn
(The University of Queensland)
- J. M. Lupton
(University of Utah
Universität Regensburg)
- C. Boehme
(University of Utah)
Abstract
Electron and hole spins in organic light-emitting diodes constitute prototypical two-level systems for the exploration of the ultrastrong-drive regime of light-matter interactions. Floquet solutions to the time-dependent Hamiltonian of pairs of electron and hole spins reveal that, under non-perturbative resonant drive, when spin-Rabi frequencies become comparable to the Larmor frequencies, hybrid light-matter states emerge that enable dipole-forbidden multi-quantum transitions at integer and fractional g-factors. To probe these phenomena experimentally, we develop an electrically detected magnetic-resonance experiment supporting oscillating driving fields comparable in amplitude to the static field defining the Zeeman splitting; and an organic semiconductor characterized by minimal local hyperfine fields allowing the non-perturbative light-matter interactions to be resolved. The experimental confirmation of the predicted Floquet states under strong-drive conditions demonstrates the presence of hybrid light-matter spin excitations at room temperature. These dressed states are insensitive to power broadening, display Bloch-Siegert-like shifts, and are suggestive of long spin coherence times, implying potential applicability for quantum sensing.
Suggested Citation
S. Jamali & V. V. Mkhitaryan & H. Malissa & A. Nahlawi & H. Popli & T. Grünbaum & S. Bange & S. Milster & D. M. Stoltzfus & A. E. Leung & T. A. Darwish & P. L. Burn & J. M. Lupton & C. Boehme, 2021.
"Floquet spin states in OLEDs,"
Nature Communications, Nature, vol. 12(1), pages 1-8, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-020-20148-6
DOI: 10.1038/s41467-020-20148-6
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