Surface Acoustic Waves Equip Materials with Active Deicing Functionality: Unraveled Deicing Mechanisms and Application to Centimeter Scale Transparent Surfaces

TL;DR

This paper demonstrates that surface acoustic waves (SAWs) can efficiently deice large, transparent surfaces made of various materials, revealing the underlying mechanisms and enabling environmentally friendly deicing solutions for industrial applications.

Contribution

It introduces a novel SAW-based deicing method applicable to transparent materials and provides fundamental insights into the mechanisms behind efficient ice removal.

Findings

SAWs can transport energy over large distances to melt ice.

Both bulk piezoelectric and piezoelectric film materials are effective for deicing.

The method is compatible with transparent surfaces and real-world operational scales.

Abstract

Migrating active deicing capabilities to transparent materials with low thermal conductivity has a high potential to improve the operations of several seminal industries in the automotive, robotic, energy, and aerospace sectors. However, the development of efficient and environmentally friendly deicing methods is yet in its infancy regarding their compatibility with end-user surfaces at relevant scales and real-world operations. Herein, we approach deicing through nanoscale surface activation enabled by surface acoustic waves (SAWs), allowing efficient on-demand deicing of surface areas spanning several square centimeters covered with thick layers of glace ice. We contemplate SAW-based deicing from a twofold perspective: First, we demonstrate its functionality both with a bulk piezoelectric material (LiNbO3) and a piezo-electric film (ZnO), the latter proving its versatile applicability to a large variety of functional materials with practical importance; second, we gain fundamental knowledge of the mechanisms responsible for efficient deicing using SAWs. In particular, we show that SAW vibrational modes easily transport energy over greater distances outside the electrode areas and efficiently melt large ice aggregates covering the materials' surfaces. In addition, the essential physics of SAW-based deicing is inferred from a carefully designed experimental and numerical study. We support our findings by providing macroscopic camera snapshots captured in situ inside a climate chamber during deicing and highly resolved laser-doppler vibrometer scans of the undisturbed wavefields at room temperature. Great care was taken to deposit the interdigital transducers (IDTs) used for SAW excitation only on ice-free areas close to the chip edges, leaving most of the substrate used for deicing unaltered and, as a matter of fact, demonstrating transparent deicing solutions.