Stretchable piezoelectric energy harvesters and self-powered sensors for wearable and implantable devices

Wearable and implantable bio-integrated electronics have started to gain momentum because of their essential role in improving the quality of life for various patients and healthy individuals. However, their continuous operation is often limited by traditional battery technologies with a limited lif...

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Bibliographic Details
Published in:	Biosensors & bioelectronics Vol. 168; p. 112569
Main Authors:	Zhou, Honglei, Zhang, Yue, Qiu, Ye, Wu, Huaping, Qin, Weiyang, Liao, Yabin, Yu, Qingmin, Cheng, Huanyu
Format:	Journal Article
Language:	English
Published:	England Elsevier B.V 15-11-2020
Subjects:	Biosensing Techniques Electric Power Supplies Humans Implantable devices Piezoelectric energy harvesters Prostheses and Implants Quality of Life Self-powered sensors Stretchable piezoelectrics Wearable devices Wearable Electronic Devices Stretchable piezoelectrics Implantable devices Wearable devices Self-powered sensors Piezoelectric energy harvesters
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Summary:	Wearable and implantable bio-integrated electronics have started to gain momentum because of their essential role in improving the quality of life for various patients and healthy individuals. However, their continuous operation is often limited by traditional battery technologies with a limited lifespan, creating a significant challenge for their development. Thus, it is highly desirable to harvest biomechanical energies from human motion for self-powered bio-integrated functional devices. Piezoelectric energy harvesters are ideal candidates to achieve this goal by converting biomechanical energy to electric energy. Because of their applications on soft and highly deformable tissues of the human body, these devices also need to be mechanically flexible and stretchable, thus posing a significant challenge. Effective methods to address the challenge include the exploration of new stretchable piezoelectric materials (e.g., hybrid composite material) and stretchable structures (e.g., buckled shapes, serpentine mesh layouts, kirigami designs, among others). This review presents an overview of the recent developments in new intrinsically stretchable piezoelectric materials and rigid inorganic piezoelectric materials with novel stretchable structures for flexible and stretchable piezoelectric sensors and energy harvesters. Following the discussion of theoretical modeling of the piezoelectric materials to convert mechanical deformations into electrical signals, the representative applications of stretchable piezoelectric materials and structures in wearable and implantable devices are briefly summarized. The present limitations and future research directions of flexible and stretchable piezoelectric devices are then discussed. •The latest developments of stretchable piezoelectric devices are comprehensively reviewed.•Stretchable piezoelectric materials and stretchable structures are summarized.•Stretchability and piezoelectricity based on different materials/structures are compared.•Applications of stretchable piezoelectric devices in biomedical devices are reviewed.•Current challenges and future opportunities for stretchable piezoelectric devices are discussed.
Bibliography:	ObjectType-Article-2 SourceType-Scholarly Journals-1 ObjectType-Feature-3 content type line 23 ObjectType-Review-1
ISSN:	0956-5663 1873-4235
DOI:	10.1016/j.bios.2020.112569