AI Article Synopsis
- Urgent development of lead-free piezoelectric energy harvesters (PEHs) is necessary to solve energy challenges and comply with environmental standards, but low output power densities hinder widespread adoption.
- An entropy-increasing strategy has been proposed, achieving an output power density of 819 μW/cm in potassium sodium niobate (KNN)-based piezoceramics and nearly doubling performance compared to lower entropy materials.
- Enhanced energy-harvesting properties are linked to increased lattice distortion, flexible polarization configurations, and randomly distributed nanodomains due to the entropy effect, leading to better durability and performance of the PEHs.
Article Abstract
It is an urgent need to develop lead-free piezoelectric energy harvesters (PEHs) to address the energy dilemma and meet environmental protection requirements. However, the low output power densities limit further promotion of lead-free PEHs for use in daily life. Here, an entropy-increasing strategy is proposed to achieve an increased output power density of 819 μW/cm in lead-free potassium sodium niobate (KNN)-based piezoceramics by increasing the configuration entropy and realizing nearly two times the growth compared with low-entropy counterparts. Evolution of the energy-harvesting performance with increasing configuration entropy is demonstrated systematically, and the excellent energy-harvesting properties achieved are attributed to the enhanced lattice distortion, the flexible polarization configuration, and the high-density randomly distributed nanodomains with the entropy-increasing effect. Moreover, excellent vibration fatigue resistance and variable temperature output power characteristics were also realized in the PEH prepared by the proposed entropy-increasing material. The significant enhancement of the comprehensive energy-harvesting performance demonstrates that the construction of KNN-based ceramics with high configuration entropy represents an effective and convenient strategy to enable design of high-performance piezoceramics and thus promotes the development of advanced PEHs.
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| http://dx.doi.org/10.1021/acsami.3c10426 | DOI Listing |
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