Excitonic signatures of ferroelectric order in parallel-stacked MoS2

Swarup Deb; Johannes Krause; Paulo E. Faria Junior; Michael Andreas Kempf; Rico Schwartz; Kenji Watanabe; Takashi Taniguchi; Jaroslav Fabian; Tobias Korn

doi:10.1038/s41467-024-52011-3

論文 Excitonic signatures of ferroelectric order in parallel-stacked MoS2

Swarup Deb ; Johannes Krause ; Paulo E. Faria Junior ; Michael Andreas Kempf ; Rico Schwartz ; Kenji Watanabe (National Institute for Materials Science) ; Takashi Taniguchi (National Institute for Materials Science) ; Jaroslav Fabian ; Tobias Korn

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Swarup Deb, Johannes Krause, Paulo E. Faria Junior, Michael Andreas Kempf, Rico Schwartz, Kenji Watanabe, Takashi Taniguchi, Jaroslav Fabian, Tobias Korn. Excitonic signatures of ferroelectric order in parallel-stacked MoS2. Nature Communications. 2024, 15 (1), 7595. https://doi.org/10.1038/s41467-024-52011-3

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(abstract)

Interfacial ferroelectricity is a phenomenon arising in a plethora of parallel-stacked layered materials,in which out-of-plane ferroelectric order is switched by in-plane sliding of adjacent layers. Unlike conventional ferroelectrics, interfacial ferroelectricity is stable against doping, potentially enabling next-generation devices with storage and computational capabilities.12 However, the field has been limited to indirect sensingor visualizing the ferroelectricity in basic bilayer units employing surface-sensitive probes. In the case of transition metal dichalcogenides, this leaves a void of in-depth knowledge about the influence of ferroelectric order on their intrinsic valley and excitonic properties. Here, we report direct far-field probing of ferroelectricity in few-layer 3R-MoS2 using reflectance contrast spectroscopy. Contrary to a simple electrostatic perception, the intralayer excitons with strictly in-plane dipole orientation are sensitive to out-of-plane ferroelectric ordering. On the other hand, despite possessing an out-of-plane electric dipole component, layer-hybridized momentum-indirect excitons remain decoupled from such ordering. Ab initio calculations elucidate the microscopic origin of the correspondence between ferroelectric order and optical response. Using a field-effect device, we demonstrate room temperature control and optical readout of multi-state polarization and its hysteretic switching. Time-resolved Kerr ellipticity measured in different ferroelectric domains reveals a direct correspondence between spin-valley dynamics and ferroelectric order.
Subject Terms Physical sciences/Nanoscience and technology/Nanoscale materials/Two-dimensional materials

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