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Correlating Optical Microspectroscopy with 4×4 Transfer Matrix Modeling for Characterizing Birefringent Van der Waals Materials

Julian Schwarz, Michael Niebauer, Maria Koleśnik‐Gray, Maximilian Szabo, Leander Baier, Phanish Chava, Artur Erbe, Vojislav Krstić, Mathias Rommel, Andreas Hutzler

2023Small Methods10 citationsDOIOpen Access PDF

Abstract

Van der Waals materials exhibit intriguing properties for future electronic and optoelectronic devices. As those unique features strongly depend on the materials' thickness, it has to be accessed precisely for tailoring the performance of a specific device. In this study, a nondestructive and technologically easily implementable approach for accurate thickness determination of birefringent layered materials is introduced by combining optical reflectance measurements with a modular model comprising a 4×4 transfer matrix method and the optical components relevant to light microspectroscopy. This approach is demonstrated being reliable and precise for thickness determination of anisotropic materials like highly oriented pyrolytic graphite and black phosphorus in a range from atomic layers up to more than 100 nm. As a key feature, the method is well-suited even for encapsulated layers outperforming state of-the-art techniques like atomic force microscopy.

Topics & Concepts

van der Waals forceBirefringenceMaterials scienceAnisotropyHighly oriented pyrolytic graphiteOptoelectronicsMatrix (chemical analysis)Transfer-matrix method (optics)Transfer matrixOpticsEllipsometryNanotechnologyGraphiteComposite materialChemistryComputer scienceThin filmPhysicsMoleculeComputer visionOrganic chemistryGraphene research and applications2D Materials and ApplicationsTransition Metal Oxide Nanomaterials
Correlating Optical Microspectroscopy with 4×4 Transfer Matrix Modeling for Characterizing Birefringent Van der Waals Materials | Litcius