Strong quenching of dye fluorescence in monomeric perylene orange/TMDC hybrid structures

Tim Völzer; Alina Schubert; Erik von der Oelsnitz; Julian Schröer; Ingo Barke; Rico Schwartz; Kenji Watanabe; Takashi Taniguchi; Sylvia Speller; Tobias Korn; Stefan Lochbrunner

doi:10.1039/d3na00276d

論文 Strong quenching of dye fluorescence in monomeric perylene orange/TMDC hybrid structures

Tim Völzer ; Alina Schubert ; Erik von der Oelsnitz ; Julian Schröer ; Ingo Barke ; Rico Schwartz ; Kenji Watanabe (National Institute for Materials Science) ; Takashi Taniguchi (National Institute for Materials Science) ; Sylvia Speller ; Tobias Korn ; Stefan Lochbrunner

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Tim Völzer, Alina Schubert, Erik von der Oelsnitz, Julian Schröer, Ingo Barke, Rico Schwartz, Kenji Watanabe, Takashi Taniguchi, Sylvia Speller, Tobias Korn, Stefan Lochbrunner. Strong quenching of dye fluorescence in monomeric perylene orange/TMDC hybrid structures. Nanoscale Advances. 2023, 5 (12), 3348-3356. https://doi.org/10.1039/d3na00276d

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(abstract)

Hybrid structures with an interface between two different materials with properly aligned energy levels facilitate photo-induced charge separation to be exploited in opto- electronic applications. Particularly, the combination of 2D transition metal dichalco- genides (TMDCs) and dye molecules offers strong light-matter interactions, tailorable band level alignments, and high fluorescence quantum yields. In this work, we aim at the charge transfer-related quenching of the fluorescence of the dye perylene orange (PO) when coated onto 2D materials. To that end, we established multiple techniques for monomer deposition, proposing a stamping approach as a solution-based entry into the preparation of hybrid structures for the 2D community and thermal vapor deposition (TVD) as a vacuum-based method particularly suited for homogenous films in the sub-monolayer regime. In the latter case, scanning force microscopy reveals an increased step-height compared to pristine flakes, suggesting that PO creeps into the interface below the flake. Via TVD, we prepare hybrid structures of PO on monolayer TMDCs and hexagonal boron nitride (hBN) as a reference. Micro-photoluminescence spectroscopy indicates monomer behavior of the PO on both substrate and on hBN flakes, while on the TMDC surface, the fluorescence is quenched. This is further confirmed by fluorescence lifetime imaging microscopy, additionally providing information on the emission decay. In line with the drastic intensity drop by up to a factor of 103 compared to the hBN reference, a reduction of the fluorescence lifetime is observed, from 3 ns to values well below 100 ps. From the ratio of the intensity quenching that is attributed to charge transfer from dye to semiconductor, we deduce a transfer time of several picoseconds, pointing to an efficient charge separation suitable for optoelectronic devices.

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