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http://hdl.handle.net/10397/119702
| Title: | Reversible giant pyroelectricity for enhanced energy harvesting and solar-driven pyro-catalysis | Authors: | Xie, M Bao, Y Hu, T Wu, J Liu, W He, S Zhang, T Guo, S Nie, H Lin, Y Huang, H Meng, N Wang, G |
Issue Date: | 6-May-2026 | Source: | Matter, 6 May 2026, v. 9, no. 5, 102708 | Abstract: | Pyroelectric energy harvesting is frequently constrained by irreversible polarization loss at phase transitions, necessitating repetitive re-poling. This study circumvents this limitation by designing a fully reversible, rhombohedral-type, ferroelectric-to-ferroelectric (FE-FE) transition in lanthanum-modified lead zirconate titanate-bismuth scandate ceramics. By optimizing the substitution level, a giant and recyclable pyroelectric response (∼60 × 10−8 C·cm−2·K−1) is achieved near ambient temperature. In situ structural analysis reveals a competitive mechanism where B–O bond expansion and A-site-dominated polarization redistribution collectively amplify temperature sensitivity. As a proof of concept, the optimized ceramics facilitate 97.6% degradation of tetracycline hydrochloride through solar-driven pyro-catalysis over 20 cycles without performance decay. These results establish phase-transition engineering as a transformative approach for self-restoring pyroelectric materials. This research paves the way for efficient utilization of ambient thermal and solar resources in energy harvesting and environmental remediation. | Keywords: | Energy harvesting Environmental remediation Ferroelectric Phase transition engineering Pyro-catalysis Pyroelectric materials |
Publisher: | Cell Press | Journal: | Matter | ISSN: | 2590-2393 | EISSN: | 2590-2385 | DOI: | 10.1016/j.matt.2026.102708 |
| Appears in Collections: | Journal/Magazine Article |
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