OLEDs as models for bird magnetoception: detecting electron spin resonance in geomagnetic fields

Grünbaum, Tobias; Milster, Sebastian; Kraus, Hermann; Ratzke, Wolfram; Kurrmann, Simon; Zeller, Viola; Bange, Sebastian; Boehme, Christoph; Lupton, John M.

doi:10.1039/c9fd00047j

Cited by 17 publications

(21 citation statements)

References 57 publications

(97 reference statements)

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“…As a consequence, magnetic resonance can even occur at zero external field, mediated alone by the local hyperfine fields. 30 Electrically detected magnetic resonance (EDMR) in OLEDs bears some resemblance to magnetic-field effects and magnetic resonance phenomena in radical-pair-based chemical reactions 31,32 but offers more flexibility in terms of choosing the crucial ratio between carrier-wave frequency (B 0 ), Rabi frequency (B 1 ) and the noise amplitude, which is determined by the local hyperfine fields. These fields, in turn, can be tuned chemically by controlling the isotopic ratio of hydrogen and deuterium.…”

Section: Discussionmentioning

confidence: 99%

“…33 Since spin-orbit coupling and resulting shifts of the gyromagnetic ratio are negligible at low frequencies, 35 hyperfine coupling pro-vides the only source of inhomogeneous broadening of the resonance. Recently, clear Zeeman resonances in EDMR were reported at frequencies as low as 5 MHz for a hydrogenated organic semiconductor; 30 for deuterated materials, this limit is expected to be much lower. It should therefore be straightforward to find a suitable parameter space where the resonance frequency is of order the typical noise frequency.…”

Section: Discussionmentioning

confidence: 99%

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Two-photon absorption in a two-level system enabled by noise

Mkhitaryan¹,

Boehme²,

Lupton³

et al. 2019

Phys. Rev. B

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We address the textbook problem of dynamics of a spin placed in a dc magnetic field and subjected to an ac drive. If the drive is polarized in the plane perpendicular to the dc field, the drive photons are resonantly absorbed when the spacing between the Zeeman levels is close to the photon energy. This is the only resonance when the drive is circularly polarized. For linearly polarized drive, additional resonances corresponding to absorption of three, five, and multiple odd numbers of photons is possible. Interaction with the environment causes the broadening of the absorption lines. We demonstrate that the interaction with environment enables the forbidden two-photon absorption. We adopt a model of the environment in the form of random telegraph noise produced by a single fluctuator. As a result of the synchronous time fluctuations of different components of the random field, the shape of the two-photon absorption line is non-Lorentzian and depends dramatically on the drive amplitude. This shape is a monotonic curve at strong drive, while, at weak drive, it develops a two-peak structure reminiscent of an induced transparency on resonance.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Two-photon absorption in a two-level system enabled by noise

Mkhitaryan¹,

Boehme²,

Lupton³

et al. 2019

Phys. Rev. B

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“…Details of the fabrication process are discussed in the Supporting Information. The OLEDs were placed on a stripline to generate the linearly polarized RF radiation of oscillating magnetic‐field amplitude B 1 , and positioned inside three pairs of Helmholtz coils to provide static magnetic fields B 0 of ≈50 nT precision and arbitrary orientation . Figure b shows a sketch of the arrangement.…”

Section: Figurementioning

confidence: 96%

“…Previously, we introduced a stripline design, with which it became possible to resolve resonances at around 100 MHz, a frequency range initially thought to be limited by the local hyperfine‐field strengths . With careful sampling, however, we recently succeeded in resolving Zeeman resonances down to 5.5 MHz in a commercially available conjugated polymer, a frequency already quite close to the electron's Larmor frequency in geomagnetic fields of ≈0.7–1.74 MHz. However, in addition to the anticipated Zeeman resonances, a further feature emerges at low RF frequency: a zero‐field peak reminiscent in structure to what has also been reported in reaction‐yield detected magnetic resonance (RYDMR) .…”

Section: Figurementioning

confidence: 99%

“…With careful sampling, however, we recently succeeded in resolving Zeeman resonances down to 5.5 MHz in a commercially available conjugated polymer, a frequency already quite close to the electron's Larmor frequency in geomagnetic fields of ≈0.7–1.74 MHz. However, in addition to the anticipated Zeeman resonances, a further feature emerges at low RF frequency: a zero‐field peak reminiscent in structure to what has also been reported in reaction‐yield detected magnetic resonance (RYDMR) . Following the results of quantum‐dynamical simulations, these features have been attributed to both the RF‐induced resonances in the local hyperfine fields as well as to the quasistatic nature of the low‐frequency RF magnetic fields experienced by short‐lived radical pairs .…”

Section: Figurementioning

confidence: 99%

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Perdeuterated Conjugated Polymers for Ultralow‐Frequency Magnetic Resonance of OLEDs

et al. 2020

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The formation of excitons in OLEDs is spin dependent and can be controlled by electron‐paramagnetic resonance, affecting device resistance and electroluminescence yield. We explore electrically detected magnetic resonance in the regime of very low magnetic fields (<1 mT). A pronounced feature emerges at zero field in addition to the conventional spin‐1/2 Zeeman resonance for which the Larmor frequency matches that of the incident radiation. By comparing a conventional π‐conjugated polymer as the active material to a perdeuterated analogue, we demonstrate the interplay between the zero‐field feature and local hyperfine fields. The zero‐field peak results from a quasistatic magnetic‐field effect of the RF radiation for periods comparable to the carrier‐pair lifetime. Zeeman resonances are resolved down to 3.2 MHz, approximately twice the Larmor frequency of an electron in Earth's field. However, since reducing hyperfine fields sharpens the Zeeman peak at the cost of an increased zero‐field peak, we suggest that this result may constitute a fundamental low‐field limit of magnetic resonance in carrier‐pair‐based systems. OLEDs offer an alternative solid‐state platform to investigate the radical‐pair mechanism of magnetic‐field effects in photochemical reactions, allowing models of biological magnetoreception to be tested by measuring spin decoherence directly in the time domain by pulsed experiments.

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Resolving the Spatial Variation and Correlation of Hyperfine Spin Properties in Organic Light‐Emitting Diodes

et al. 2022

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under the application of relatively weak magnetic fields point toward their application as quantum sensors at room temperature. [17,18] Their fabrication flexibility and industrial use in commercial displays [19] underlie recent advances toward the miniaturization and integration of quantum technologies based on these materials. [20][21][22] For effective integration or miniaturization, reproducibility is crucial, and this extends to those properties of materials which impact spin-dependent processes. In this work, we aim to measure the variation of a critical spin property common to organic materials, the Overhauser field, which arises from the hyperfine coupling of charge-carrier spins to the bath of randomly oriented nuclear spins in the molecular environment. [23] The Overhauser field underlies a range of phenomena observed in organic devices, including magnetoresistive and magnetic resonant effects in organic light-emitting diodes (OLEDs), [24][25][26][27][28] both of which have been proposed as a mechanism to enable magnetic field sensing. [17,26] To date, the Overhauser field has been treated as a bulk property of the device, characterized by a single value that describes its impact. [26,29] If this is not a good assumption, it will present a significant challenge as we move toward high spatial resolution of magnetic fields [30,31] in organic devices. [32,33] We will demonstrate in the following sections that the Overhauser field indeed shows substantial intra-device variation by spatially resolving the magnetoluminescence effect exhibited by both a copolymer Super Yellow poly(phenylene-vinylene) (SY-PPV) and a small-molecule tris-(8-hydroxyquinoline) aluminum (Alq 3 ) OLED. As the Overhauser field is central to a wide range of spin-enabled functionality in organic devices, this variation presents a fundamental challenge for efforts to miniaturize and integrate such devices. Concept Magneto-Electroluminescence in OLEDsWe employ a stable and widely investigated active material-SY-PPV-to characterize the spatial variation of the Overhauser field in a simple vertical structure OLED (Figure 1a) and extract Devices that exploit the quantum properties of materials are widespread, with quantum information processors and quantum sensors showing significant progress. Organic materials offer interesting opportunities for quantum technologies owing to their engineerable spin properties, with spintronic operation and spin resonance magnetic-field sensing demonstrated in research grade devices, as well as proven compatibility with large-scale fabrication techniques. Yet several important challenges remain as moving toward scaling these proof-of-principle quantum devices to larger integrated logic systems or spatially smaller sensing elements, particularly those associated with the variation of quantum properties both within and between devices. Here, spatially resolved magnetoluminescence is used to provide the first 2D map of a hyperfine spin property-the Overhauser field-in traditional organic light-emitting diodes (...

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OLEDs as models for bird magnetoception: detecting electron spin resonance in geomagnetic fields

Cited by 17 publications

References 57 publications

Two-photon absorption in a two-level system enabled by noise

Two-photon absorption in a two-level system enabled by noise

Perdeuterated Conjugated Polymers for Ultralow‐Frequency Magnetic Resonance of OLEDs

Resolving the Spatial Variation and Correlation of Hyperfine Spin Properties in Organic Light‐Emitting Diodes

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