Affiliation:
1. State Key Laboratory of New Ceramics and Fine Processing, School of Materials Science and Engineering Tsinghua University Beijing P. R. China
2. State Key Laboratory of Information Photonics and Optical Communications, School of Science Beijing University of Posts and Telecommunications Beijing P. R. China
3. Research Center for Advanced Functional Ceramics Wuzhen Laboratory Jiaxing P. R. China
4. Department of Teaching and Researching of Social and Ecological Civilization Party School of the Central Committee of C.P.C. (National Academy of Governance) Beijing P. R. China
5. Tongxiang Tsingfeng Technology Co. Ltd Jiaxing P. R. China
Abstract
AbstractOver the years, lead‐based piezoelectric ceramics found extensive use in vital fields such as sensors and actuators. Despite their exceptional electromechanical properties, lead‐containing materials pose severe environmental risks and foster a new era of lead‐free piezoelectric materials after decades of research. However, recent comparative assessments of potassium sodium niobate (KNN) versus lead zirconate titanate (PZT) piezoelectric materials proposed that the environmental damage already presented before use due to raw material extraction and processing, invoking concerns on the true greenness of the lead‐free alternatives. Nevertheless, many other factors deserve further consideration, for example, reference geometry and life cycle stage. Herein, the comprehensive life cycle assessment is undertaken on PZT and KNN‐based ceramics with a unit volume of 0.001 m3 from cradle to gate. Results show that PZT exhibits higher negative impacts than KNN‐based counterparts, attributed to lead extraction, processing, and associated environmental emissions. Across primary quantitative impact indicators from toxicity, environmental, and resource aspects, KNN‐based ceramics impose fewer risks on the environment and human health, with the overall impact being only 28% of PZT ceramics. Still, more efficient methods are required for KNN‐based ceramics to reduce the high energy consumption and emission during extraction and purification of raw material Nb2O5. This work not only offers critical insights for material development but also serves as a multifaceted reference for advanced fabrication technologies.image
Funder
National Natural Science Foundation of China
Key Research and Development Program of Zhejiang Province
Natural Science Foundation of Zhejiang Province
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