Piezoelectric biomolecules for lead-free, reliable, eco-friendly electronics Sarah Guerin 1,2 1 Synthesis and Solid State Pharmaceutical Centre, University of Limerick, Ireland 2 Department of Physics, Bernal Institute, University of Limerick, Ireland Billions of piezoelectric sensors are produced every year, improving the efficiency of many current and emerging technologies. By interconverting electrical and mechanical energy they enable medical device, infrastructure, automotive and aerospace industries, but with a huge environmental cost. The majority of piezoelectric sensors contain Lead Zirconium Titanate (PZT), the fabrication of which requires toxic lead oxide. Prominent lead-free alternatives are heavily processed, and rely on expensive, non-renewable materials such as Niobium. Biological materials such as amino acids and peptides have emerged as exciting new piezoelectrics. Biomolecular-crystal assemblies can be grown at room temperature with no by-products, and do not require an external electric field to induce piezoelectricity, unlike PZT and other piezoceramics. Currently no research is focused on developing these crystals as reliable, solid-state sensors to integrate into conventional electronic devices, due to their high water solubility, uncontrolled growth, variable piezoelectric response, and difficulty in making electrical contact. Our research is taking on the challenge of developing biomolecular crystals as organic, low-cost, high- performance sensors, to out-perform and phase-out inorganic device components with dramatically reduced environmental impact. In this talk we will discuss our methodologies for the design, growth, and engineering of these novel piezoelectric materials under three pillars: • An ambitious computational workflow to enable the design of super-piezoelectric crystalline assemblies by combining high-throughput quantum mechanical calculations with machine learning algorithms. • A new method of growing polycrystalline biomolecules, allowing for easy, efficient creation of macroscopic piezoelectric structures. • Establishing effective electromechanical testing procedures to characterise fully insulated and contacted biomolecular device components. References 1. E. Fukada and I. Yasuda, Japanese Journal of Applied Physics 3, 117 (1964). 2. D. Denning et al., ACS Biomaterials Science & Engineering 3, 929 (2017). 3. Y. Liu, Y. Wang, M.-J. Chow, N. Q. Chen, F. Ma, Y. Zhang, and J. Li, Physical review letters 110, 168101 (2013). 4. Y. Liu et al., Proceedings of the National Academy of Sciences 111, E2780 (2014). 5. Y. Ando and E. Fukada, Journal of Polymer Science: Polymer Physics Edition 14, 63 (1976). 6. B. Y. Lee, J. Zhang, C. Zueger, W.-J. Chung, S. Y. Yoo, E. Wang, J. Meyer, R. Ramesh, and S.-W. Lee, Nature nanotechnology 7, 351 (2012). 7. I. W. Park, K. W. Kim, Y. Hong, H. J. Yoon, Y. Lee, D. Gwak, and K. Heo, Nanomaterials 10, 93 (2020). 8. K. Tao et al., Energy & Environmental Science (2020). 9. S. Guerin et al., Nature Materials 17, 180 (2017). 10. S. Guerin, S. A. Tofail, and D. Thompson, Crystal Growth & Design 18, 4844 (2018). 11. S. Guerin, J. O’Donnell, E. U. Haq, C. McKeown, C. Silien, F. M. Rhen, T. Soulimane, S. A. Tofail, and D. Thompson, Physical review letters 122, 047701 (2019). 12. S. Guerin, S. A. Tofail, and D. Thompson, NPG Asia Materials 11, 10 (2019).
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