Mid-Infrared Mapping of Four-Layer Graphene Polytypes Using Near-Field Microscopy

The mid-infrared (MIR) spectral region attracts attention for accurate chemical analysis using photonic devices. Few-layer graphene (FLG) polytypes are promising platforms, due to their broad absorption in this range and gate-tunable optical properties. Among these polytypes, the noncentrosymmetric...

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Veröffentlicht in:	Nano letters 2023-12, Vol.23 (23), p.10758-10764
Hauptverfasser:	Beitner, Daniel, Amitay, Shaked, Salleh Atri, Simon, McEllistrim, Andrew, Coen, Tom, Fal’ko, Vladimir I., Richter, Shachar, Ben Shalom, Moshe, Suchowski, Haim
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creator	Beitner, Daniel Amitay, Shaked Salleh Atri, Simon McEllistrim, Andrew Coen, Tom Fal’ko, Vladimir I. Richter, Shachar Ben Shalom, Moshe Suchowski, Haim
description	The mid-infrared (MIR) spectral region attracts attention for accurate chemical analysis using photonic devices. Few-layer graphene (FLG) polytypes are promising platforms, due to their broad absorption in this range and gate-tunable optical properties. Among these polytypes, the noncentrosymmetric ABCB/ACAB structure is particularly interesting, due to its intrinsic bandgap (8.8 meV) and internal polarization. In this study, we utilize scattering-scanning near-field microscopy to measure the optical response of all three tetralayer graphene polytypes in the 8.5–11.5 μm range. We employ a finite dipole model to compare these results to the calculated optical conductivity for each polytype obtained from a tight-binding model. Our findings reveal a significant discrepancy in the MIR optical conductivity response of graphene between the different polytypes than what the tight-binding model suggests. This observation implies an increased potential for utilizing the distinct tetralayer polytypes in photonic devices operating within the MIR range for chemical sensing and infrared imaging.
doi_str_mv	10.1021/acs.nanolett.3c02819
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title	Mid-Infrared Mapping of Four-Layer Graphene Polytypes Using Near-Field Microscopy
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