Litcius/Paper detail

Tailored ultrasound propagation in microscale metamaterials via inertia design

Rachel Sun, Jet Lem, Yun Kai, Washington DeLima, Carlos M. Portela

2024Science Advances26 citationsDOIOpen Access PDF

Abstract

The quasi-static properties of micro-architected (meta)materials have been extensively studied over the past decade, but their dynamic responses, especially in acoustic metamaterials with engineered wave propagation behavior, represent a new frontier. However, challenges in miniaturizing and characterizing acoustic metamaterials in high-frequency (megahertz) regimes have hindered progress toward experimentally implementing ultrasonic-wave control. Here, we present an inertia design framework based on positioning microspheres to tune responses of 3D microscale metamaterials. We demonstrate tunable quasi-static stiffness by up to 75% and dynamic longitudinal-wave velocities by up to 25% while maintaining identical material density. Using noncontact laser-based dynamic experiments of tunable elastodynamic properties and numerical demonstrations of spatio-temporal ultrasound wave propagation, we explore the tunable static and elastodynamic property relation. This design framework expands the quasi-static and dynamic metamaterial property space through simple geometric changes, enabling facile design and fabrication of metamaterials for applications in medical ultrasound and analog computing.

Topics & Concepts

Microscale chemistryMetamaterialInertiaAcousticsMaterials scienceUltrasonic sensorFlexibility (engineering)Computer scienceOptoelectronicsPhysicsClassical mechanicsMathematicsStatisticsMathematics educationAcoustic Wave Phenomena ResearchCellular and Composite StructuresMusic Technology and Sound Studies