Litcius/Paper detail

3D alignment of distant patterns with deep-subwavelength precision using metasurfaces

Maryam Ghahremani, Andrew McClung, Babak Mirzapourbeinekalaye, Amir Arbabi

2024Nature Communications16 citationsDOIOpen Access PDF

Abstract

Measurement of the relative positions of two objects in three dimensions with sub-nanometer precision is essential to fundamental physics experiments and applications such as aligning multi-layer patterns of semiconductor chips. Existing methods, which rely on microscopic imaging and registration of distant patterns, lack the required accuracy and precision for the next generation of three-dimensional (3D) chips. Here we show that 3D misalignment between two distant objects can be measured using metasurface alignment marks, a laser, and a camera with sub-nanometer precision. Through simulations, we demonstrate that the shot noise-limited precisions of the lateral and axial misalignments between the marks are λ0/50, 000 and λ0/6, 300 (λ0: laser’s wavelength), respectively. With its high precision and simplicity, the technique enables the next generation of 3D-integrated optical and electronic chips and paves the way for developing cost-effective and compact sensors relying on sub-nanometer displacement measurements. Metasurface alignment marks enable precise 3D measurement of relative positions of distant objects using only a laser and a camera, achieving sub-nanometer precision. Applications include 3D chips manufacturing and displacement sensors.

Topics & Concepts

Computer scienceOpticsPhysicsMetamaterials and Metasurfaces ApplicationsAdvanced Antenna and Metasurface TechnologiesAntenna Design and Analysis
3D alignment of distant patterns with deep-subwavelength precision using metasurfaces | Litcius