Litcius/Paper detail

Bulk Ferroelectric Metamaterial with Enhanced Piezoelectric and Biomimetic Mechanical Properties from Additive Manufacturing

Jun Li, Fan Yang, Yin Long, Yutao Dong, Yizhan Wang, Xudong Wang

2021ACS Nano56 citationsDOIOpen Access PDF

Abstract

Three-dimensional (3D) ferroelectric materials are electromechanical building blocks for achieving human–machine interfacing, energy sustainability, and enhanced therapeutics. However, current natural or synthetic materials cannot offer both a high piezoelectric response and desired mechanical toughness at the same time to meet the practicality. Here, a lamellar ferroelectric metamaterial was created with a ceramic-like piezoelectric property and a bone-like fracture toughness through a low-voltage-assisted 3D printing technology. The one-step printed bulk structure, consisting of periodically intercalated soft ferroelectric and hard electrode layers, exhibited a significantly enhanced longitudinal piezoelectric charge coefficient (d33) of over 150 pC N–1, as well as a superior fracture resistance of ∼5.5 MPa·m1/2, more than three times higher than conventional piezo-ceramics. The excellent printability together with the combination of both high piezoelectric and mechanical behaviors allowed us to create a bone-like structure with tunable anisotropic piezoelectricity and bone-comparable mechanical properties, showing a potential of manufacturing practical, high-performance, and smart biological systems.

Topics & Concepts

Materials sciencePiezoelectricityComposite materialFerroelectricityPiezoelectric coefficientCeramicFracture toughnessLamellar structureToughnessMetamaterialOptoelectronicsDielectricAdvanced Sensor and Energy Harvesting MaterialsAdditive Manufacturing and 3D Printing TechnologiesTactile and Sensory Interactions