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Main Authors: Atwood, S. I., Hosseinzadeh, S., Mkhitaryan, V. V., Tennahewa, T. H., Malissa, H., Jiang, W., Darwish, T. A., Burn, P. L., Lupton, J. M., Boehme, C.
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2310.14180
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author Atwood, S. I.
Hosseinzadeh, S.
Mkhitaryan, V. V.
Tennahewa, T. H.
Malissa, H.
Jiang, W.
Darwish, T. A.
Burn, P. L.
Lupton, J. M.
Boehme, C.
author_facet Atwood, S. I.
Hosseinzadeh, S.
Mkhitaryan, V. V.
Tennahewa, T. H.
Malissa, H.
Jiang, W.
Darwish, T. A.
Burn, P. L.
Lupton, J. M.
Boehme, C.
contents We present Floquet theory-based predictions and electrically detected magnetic resonance (EDMR) experiments scrutinizing the nature of two-photon magnetic resonance shifts of charge-carrier spin states in the perdeuterated $π$-conjugated polymer poly[2-methoxy-5-(2'-ethylhexyloxy)-1,4-phenylene vinylene] (d-MEH-PPV) under strong magnetic resonant drive conditions (radiation amplitude $B_1$ ~ Zeeman field $B_0$). Numerical calculations show that the two-photon resonance shift with power is nearly drive-helicity independent. This is in contrast to the one-photon Bloch-Siegert shift that only occurs under non-circularly polarized strong drive conditions. We therefore treated the Floquet Hamiltonian analytically under arbitrary amplitudes of the co- and counter-rotating components of the radiation field to gain insight into the nature of the helicity dependence of multi-photon resonance shifts. In addition, we tested Floquet-theory predictions experimentally by comparing one-photon and two-photon charge-carrier spin resonance shifts observed through room-temperature EDMR experiments on d-MEH-PPV-based bipolar injection devices [i.e., organic light emitting diode structures (OLEDs)]. We found that under the experimental conditions of strong, linearly polarized drive, our observations consistently agree with theory, irrespective of the magnitude of $B_1$, and therefore underscore the robustness of Floquet theory in predicting nonlinear magnetic resonance behaviors.
format Preprint
id arxiv_https___arxiv_org_abs_2310_14180
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Non-Bloch-Siegert-type power-induced shift of two-photon electron paramagnetic resonances of charge-carrier spin states in an OLED
Atwood, S. I.
Hosseinzadeh, S.
Mkhitaryan, V. V.
Tennahewa, T. H.
Malissa, H.
Jiang, W.
Darwish, T. A.
Burn, P. L.
Lupton, J. M.
Boehme, C.
Mesoscale and Nanoscale Physics
We present Floquet theory-based predictions and electrically detected magnetic resonance (EDMR) experiments scrutinizing the nature of two-photon magnetic resonance shifts of charge-carrier spin states in the perdeuterated $π$-conjugated polymer poly[2-methoxy-5-(2'-ethylhexyloxy)-1,4-phenylene vinylene] (d-MEH-PPV) under strong magnetic resonant drive conditions (radiation amplitude $B_1$ ~ Zeeman field $B_0$). Numerical calculations show that the two-photon resonance shift with power is nearly drive-helicity independent. This is in contrast to the one-photon Bloch-Siegert shift that only occurs under non-circularly polarized strong drive conditions. We therefore treated the Floquet Hamiltonian analytically under arbitrary amplitudes of the co- and counter-rotating components of the radiation field to gain insight into the nature of the helicity dependence of multi-photon resonance shifts. In addition, we tested Floquet-theory predictions experimentally by comparing one-photon and two-photon charge-carrier spin resonance shifts observed through room-temperature EDMR experiments on d-MEH-PPV-based bipolar injection devices [i.e., organic light emitting diode structures (OLEDs)]. We found that under the experimental conditions of strong, linearly polarized drive, our observations consistently agree with theory, irrespective of the magnitude of $B_1$, and therefore underscore the robustness of Floquet theory in predicting nonlinear magnetic resonance behaviors.
title Non-Bloch-Siegert-type power-induced shift of two-photon electron paramagnetic resonances of charge-carrier spin states in an OLED
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2310.14180