ACS Nano 2025, 19, 24884−24894

Abstract: Piezoelectric biomaterials hold immense potential for next-generation microdevices, yet their piezoelectric performance often trails behind that of conventional synthetic counterparts. This study demonstrates a dual-scale polarization strategy to significantly enhance the piezoelectric response of d-phenylalanine derivatives (d-PheAD). Molecular-level polarization is amplified through ionic interactions with l-glutamic acid-modified Fe3O4 magnetic nanoparticles, while macroscopic alignment of d-PheAD nanoarrays under magnetic fields optimizes collective dipole orientation. This synergistic approach elevates the effective piezoelectric coefficient (deff) from 10.4 to 121.9 pm V–1, outperforming most biomaterial-based piezoelectric systems and many inorganic piezoelectric systems. Integrating these engineered assemblies into a triboelectric-enhanced piezoelectric nanogenerator yields unprecedented electrical outputs (2853 nA, 51.9 V), a 25-fold improvement over baseline configurations. The device achieves real-time detection of trace HCl gas at low concentrations, demonstrating superior sensitivity compared to commercial electrochemical sensors. By bridging molecular design and macroscopic engineering, this work establishes a scalable paradigm for deploying eco-friendly piezoelectric biomaterials in high-performance microelectronics and environmental monitoring technologies.

doi.org/10.1021/acsnano.5c03436