Quantifying Twist Angles in Cuprate Heterostructures with Anisotropic Raman Signatures

TL;DR

This paper presents a non-invasive polarization-resolved Raman spectroscopy method to accurately determine twist angles in cuprate heterostructures, enabling precise characterization crucial for exploring angle-dependent quantum phenomena.

Contribution

It introduces a novel Raman-based technique utilizing anisotropic vibrational modes for twist angle measurement in cuprate heterostructures, avoiding damage from conventional methods.

Findings

Identified optical fingerprints of twist angles via anisotropic Raman modes.

Demonstrated high-resolution, non-destructive measurement of twist angles.

Enabled reliable characterization without damaging sensitive cuprate layers.

Abstract

Artificially engineered twisted van der Waals (vdW) heterostructures have unlocked new pathways for exploring emergent quantum phenomena and strongly correlated electronic states. Many of these phenomena are highly sensitive to the twist angle, which can be deliberately tuned to tailor the interlayer interactions. This makes the twist angle a critical tunable parameter, emphasizing the need for precise control and accurate characterization during device fabrication. In particular, twisted cuprate heterostructures based on Bi2Sr2CaCu2O8+x have demonstrated angle-dependent superconducting properties, positioning the twist angle as a key tunable parameter. However, the twisted interface is highly unstable under ambient conditions and vulnerable to damage from conventional characterization tools such as electron microscopy or scanning probe techniques. In this work, we introduce a fully non-invasive, polarization-resolved Raman spectroscopy approach for determining twist angles in artificially stacked BSCCO heterostructures. By analyzing twist-dependent anisotropic vibrational Raman modes, particularly utilizing the out-of-plane A1g vibrational mode of Bi/Sr at 116 cm-1, we identify clear optical fingerprints of the rotational misalignment between cuprate layers. Our high-resolution confocal Raman setup, equipped with polarization control and RayShield filtering down to 10 cm-1, allows for reliable and reproducible measurements without compromising the material's structural integrity.