Data underlying paper III. "... Multimethod study for films of the blue fluorescent emitter MADN"

DOI:10.4121/d320a48b-aed4-49c3-9885-82cbac8ffe5d.v1
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DOI: 10.4121/d320a48b-aed4-49c3-9885-82cbac8ffe5d

Datacite citation style

de Jong, Eline; de Rooij, N.G.; van Geel, W.F.M.; Hauenstein, C.; Tomita, Hiroki et. al. (2025): Data underlying paper III. "... Multimethod study for films of the blue fluorescent emitter MADN". Version 1. 4TU.ResearchData. dataset. https://doi.org/10.4121/d320a48b-aed4-49c3-9885-82cbac8ffe5d.v1
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Dataset

Figure data of paper "Electron affinity and binding energy of excitons in disordered organic semiconductors. III. Multimethod study for films of the blue fluorescent emitter MADN", accepted for publication in Physical Review B (2025).


Abstract: A method is developed for deducing the electron affinity of disordered organic semiconductors from spectroscopic thin-film studies of the ionization energy and the optical gap energy, combined with field-induced dissociation (FID) device experiments that are analyzed with Kinetic Monte Carlo simulations using a methodology that has been presented by E.J. de Jong et al. (Phys. Rev, B, xx, yy (20zz)). The FID experiments are carried out for a set of eight organic semiconductor materials that are often used in organic light-emitting diodes (OLEDs). The analysis is focused on the α and β-isomers of the blue fluorescent emitter material 2-methyl-9,10-di-naphthyl-anthracene (MADN). For these two materials, the experimental ionization energy, the optical gap energy, the exciton binding energy and the electron affinity, are shown to be consistent with the results of quantum-chemical calculations, presented by G. Tirimb`o et al. (Phys. Rev, B, xx, yy (20zz)).

For all fluorescent emitter materials studied, the FID experiments reveal an exciton binding energy of approximately 1.0–1.2 eV, whereas for a thermally-activated delayed fluorescence material a slightly smaller value is obtained.

History

  • 2025-10-31 first online, published, posted

Publisher

4TU.ResearchData

Format

Mathematica notebook / .nb

Funding

  • NWO-project "Suppressing Exciton Quenching in OLEDs: an Integrated Approach" (SEQUOIA, project No. 18975) of the research program “Open Technology” of the Dutch Research Council (grant code project No. 18975) NWO
  • Marie Sklodowska-Curie grant agreement TADFlife (grant code Project No. 812872) EU Horizon 2020 research and innovation programme

Organizations

TU Eindhoven, Department of Applied Physics and Science Education

DATA

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