Acoustic-Assisted Fabrication of Thin Shells with Spatially Distributed Imperfections

TL;DR

This paper presents an innovative acoustic-assisted fabrication technique to create thin shells with controlled, spatially distributed imperfections, enabling systematic study and tuning of their buckling behavior for engineering applications.

Contribution

It introduces a scalable method to produce shells with vibrational mode-shaped imperfections, advancing the understanding of imperfection-sensitive mechanics in thin-shell structures.

Findings

Imperfection geometry can be tuned by acoustic frequency.

Amplitude of imperfections increases with acoustic volume.

Buckling experiments show significant reduction in critical pressure.

Abstract

Thin-shell structures, found in biological systems such as beetle carapaces and widely used in aerospace, civil, and mechanical engineering, achieve remarkable strength-to-mass ratio given their slenderness and curved geometries. However, their load-bearing capacity is highly sensitive to geometric imperfections, which are often unavoidable during fabrication and can trigger subcritical buckling. Silicone-based hemispherical domes have served as an experimental modal system to study this phenomenon, yet prior work has largely focused on localized dimples or flat imperfections, failing to capture the spatially distributed nature of real-world imperfection patterns. Here, we introduce an acoustic-assisted method for fabricating thin shells with spatially distributed, vibrational mode-shaped imperfections. Silicone is cast onto a thick elastic mold excited by a speaker, and vibration-induced flow during curing creates thickness variations. High-speed imaging and microCT scanning reveal accumulation of material at the antinodes of the mold's vibrational modes. We show that imperfection geometry can be tuned by acoustic frequency, while their amplitude increases with acoustic volume. Buckling experiments demonstrate significant reductions in critical pressure, offering a scalable platform to study and tune imperfection-sensitive mechanics. Beyond shell mechanics, we offer a scalable and tunable fabrication method for patterning soft materials in applications ranging from morphable surfaces to bioinspired design.