Polar enhancement of optical nonlinearities and domain-driven second harmonic contrast in bismuth telluro-halide van der Waals crystals

TL;DR

This study reveals giant anisotropic nonlinear optical responses in polar bismuth telluro-halide van der Waals crystals, demonstrating their potential for nanoscale nonlinear photonics through polarization-resolved SHG microscopy.

Contribution

It introduces the use of SHG polarimetry and microscopy to explore and visualize nonlinear optical properties and domain structures in BiTeX vdW materials, highlighting their unique polar and nonlinear characteristics.

Findings

Giant anisotropic nonlinearities driven by permanent dipole moments.

Distinct SHG spatial textures reveal domain boundaries and symmetry restoration.

BiTeX materials are promising for domain-engineered nonlinear photonics.

Abstract

The BiTeX family of polar van der Waals (vdW) semiconductors offers a unique platform for exploring the interplay between polar crystalline structure and nonlinear optical phenomena. Here, we utilize second harmonic generation (SHG) polarimetry to demonstrate giant anisotropic optical nonlinearities in BiTeBr and BiTeI driven by contributions to the crystals' nonlinear polarizability originating from their permanent dipole moment. In addition, using SHG microscopy, we show that BiTeI displays a distinctive SHG spatial texture consisting of thread-like regions of reduced harmonic intensity. These features demark the boundaries between phase and anti-phase polar domains, confirmed via piezoresponse force microscopy and are attributable to disorder-driven restoration of inversion symmetry and concomitant optical interference effects. Our results unveil the power of polarization-resolved SHG microscopy in elucidating the intricate relationship between structure, symmetry, and nonlinear optical responses in polar vdW materials and highlight the promise of BiTeX as a material platform for domain-engineered nanoscale nonlinear photonics.