TY - JOUR
T1 - Wearable Nanocomposite Textile-Based Piezoelectric and Triboelectric Nanogenerators: Progress and Perspectives
AU - Bairagi, Satyaranjan
AU - Ul-Islam, Shahid
AU - Kumar, Charchit
AU - Babu, Aswathy
AU - Aliyana, Akshaya Kumar
AU - Stylios, George
AU - Pillai, Suresh C.
AU - Mulvihill, Daniel M.
N1 - Funding Information:
Satyaranjan Bairagi is a Research Associate under a project funded by EPSRC (Engineering and Physical Sciences Research Council), at the University of Glasgow, United Kingdom. He completed his Ph.D. in Material Science from Indian Institute of Technology- Delhi, India. His area of research interest includes development of nanotechnology based piezoelectric and triboelectric materials for nanogenerators as well as textile based flexible advanced materials for renewable energy harvesting. He has published numerous research articles in various reputed peer-reviewed journals. In addition, Dr. Bairagi has published and written more than 30 book chapters which have been published and submitted in different books under various publishers such as Elsevier, Wiley, Springer and so forth.
Funding Information:
Aswathy Babu obtained her Ph.D. in Chemistry from University of Kerala, India in 2015 and subsequently undertook postdoctoral periods at the CSIR-NIIST, India, worked on the development of functional plasmonic and bio-nanomaterials for SERS applications. Currently, she is a post-doctoral researcher at Atlantic Technological University, Sligo, Ireland working on the project funded by SFI-EPSRC. Her current research interest is in the area of energy materials, especially; the development of textile triboelectric nanogenerators (T-TENGs) for wearable electronic applications and fabrication of functional nanomaterials for advanced oxidation processes.
Funding Information:
This work was supported by the UK Engineering and Physical Sciences Research Council (EPSRC) (Ref. EP/V003380/1 ) ‘Next Generation Energy Autonomous Textile Fabrics based on Triboelectric Nanogenerators’ and also by Science Foundation Ireland ( SFI-20/ EPSRC/3710 ).
Publisher Copyright:
© 2023 The Authors
PY - 2023/12/15
Y1 - 2023/12/15
N2 - In recent years, the widespread adoption of next-generation wearable electronics has been facilitated by the integration of advanced nanogenerator technology with conventional textiles. This integration has led to the development of textile-based nanogenerators (t-NGs), which hold tremendous potential for harvesting mechanical energy from the surrounding environment and serving as power sources for self-powered electronics. Textile structures are inherently flexible, making them well-suited for wearable applications. However, their electrical performance as nanogenerators is significantly limited when used without any modifications. To address this limitation and enhance the electrical performance of textile-based nanogenerators, nanocomposite textiles have been extensively utilized for fabricating advanced nanogenerators. This critical review focuses on the recent progress in wearable nanocomposite textiles-based piezoelectric and triboelectric nanogenerators. The review covers the fundamentals of piezoelectricity and triboelectricity, the working principles of nanogenerators, and the selection of materials. Furthermore, it provides a detailed discussion of nanocomposite textiles in various forms, such as fibers or yarns, fabrics, and electrospun nanofibrous webs, which are employed in piezoelectric and triboelectric nanogenerators. The review also highlights the challenges associated with their implementation and outlines the prospects of textile-based nanogenerators. It can be concluded that nanocomposite textile based piezoelectric and triboelectric nanogenerators exhibit better electrical output and mechanical strength compared to conventional textile based nanogenerators. Nanocomposite electrospun web based piezoelectric nanogenerators exhibit higher piezoelectric output compared with nanocomposite fibre/yarn or fabric based piezoelectric nanogenerators. This is because an in-situ poling takes place in electrospinning unlike with fibre or fabric based piezoelectric nanogenerators. Nanocomposite electrospun web based triboelectric nanogenerators also show better triboelectric output compared to the fibre or fabric-based equivalents. This is due to the higher contact area developed with electrospun nanocomposite webs compared to the fibre or fabric cases. Overall, it can be concluded that while nanocomposite construction can boost output and durability of textile based nanogenerators, more research is required to bring output, stability and durability up to the levels achievable with non-textile based devices.
AB - In recent years, the widespread adoption of next-generation wearable electronics has been facilitated by the integration of advanced nanogenerator technology with conventional textiles. This integration has led to the development of textile-based nanogenerators (t-NGs), which hold tremendous potential for harvesting mechanical energy from the surrounding environment and serving as power sources for self-powered electronics. Textile structures are inherently flexible, making them well-suited for wearable applications. However, their electrical performance as nanogenerators is significantly limited when used without any modifications. To address this limitation and enhance the electrical performance of textile-based nanogenerators, nanocomposite textiles have been extensively utilized for fabricating advanced nanogenerators. This critical review focuses on the recent progress in wearable nanocomposite textiles-based piezoelectric and triboelectric nanogenerators. The review covers the fundamentals of piezoelectricity and triboelectricity, the working principles of nanogenerators, and the selection of materials. Furthermore, it provides a detailed discussion of nanocomposite textiles in various forms, such as fibers or yarns, fabrics, and electrospun nanofibrous webs, which are employed in piezoelectric and triboelectric nanogenerators. The review also highlights the challenges associated with their implementation and outlines the prospects of textile-based nanogenerators. It can be concluded that nanocomposite textile based piezoelectric and triboelectric nanogenerators exhibit better electrical output and mechanical strength compared to conventional textile based nanogenerators. Nanocomposite electrospun web based piezoelectric nanogenerators exhibit higher piezoelectric output compared with nanocomposite fibre/yarn or fabric based piezoelectric nanogenerators. This is because an in-situ poling takes place in electrospinning unlike with fibre or fabric based piezoelectric nanogenerators. Nanocomposite electrospun web based triboelectric nanogenerators also show better triboelectric output compared to the fibre or fabric-based equivalents. This is due to the higher contact area developed with electrospun nanocomposite webs compared to the fibre or fabric cases. Overall, it can be concluded that while nanocomposite construction can boost output and durability of textile based nanogenerators, more research is required to bring output, stability and durability up to the levels achievable with non-textile based devices.
KW - Energy harvesting
KW - Nanocomposite textiles
KW - Piezoelectric nanogenerator
KW - Self-powered devices
KW - Textile -based nanogenerators (t-NGs)
KW - Triboelectric nanogenerator
UR - http://www.scopus.com/inward/record.url?scp=85174159990&partnerID=8YFLogxK
U2 - 10.1016/j.nanoen.2023.108962
DO - 10.1016/j.nanoen.2023.108962
M3 - Article
SN - 2211-2855
VL - 118
JO - Nano Energy
JF - Nano Energy
IS - Part B
M1 - 108962
ER -