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O: Fachverband Oberflächenphysik

O 96: Plasmonics and Nanooptics: Light-Matter Interaction, Spectroscopy II

O 96.8: Vortrag

Freitag, 21. März 2025, 12:15–12:30, H4

High-Throughput Phonon Polariton Materials Discovery from First Principles — •Elena Gelzinyte¹, Giulia Carini¹, Niclas S. Mueller¹, Martin Wolf¹, Karsten Reuter¹, Johannes T. Margraf², Alexander Paarmann¹, and Christian Carbogno¹ — ¹Fritz-Haber-Institut der MPG, Berlin — ²University of Bayreuth

Phonon Polaritons (PhPs), quasi-particles that arise from strong coupling between infrared photons and optical lattice vibrations, are promising in nanophotonic applications for highly directional and confined light propagation with low optical loss [1]. However, little is still known about the trends in material space that drive the emergence and characteristics of PhPs. To describe these trends, we compute the permittivity function [2] as the basis for describing PhP dispersion. We employ Kubo’s linear-response theory, where the harmonic and anharmonic phonon properties as well as Born effective charges are used to model the involved couplings. This approach is validated on materials with well-characterised PhP behaviour, such as h-BN, MoO₃ and β-Ga₂O₃, and then applied to 5,000 materials from the JARVIS database [3]. By analysing the trends emerging from these data, we identify qualitative metrics that capture the material’s ability to support PhPs. Finally, we highlight some examples and outliers of this high-throughput screening process.

[1] E. Galiffi et al., Nat. Rev. Mater. 9, 9 (2024).

[2] M. Born & K. Huang, Dynamical Theory of Crystal Lattices (1954).

[3] K. Choudhary et al., npj Comput. Mater. 6, 1 (2020).

Keywords: Permittivity Function; Phonon Polaritons; High-throughput; Light-matter coupling