Ferroelectric Materials for Energy Harvesting and Storage

Woodhead Publishing Ltd
  • erscheint ca. am 1. September 2020
  • Buch
  • |
  • Softcover
  • |
  • 500 Seiten
978-0-08-102802-5 (ISBN)
The need to more efficiently harvest energy for electronics has spurred investigation into materials that can harvest energy from locally abundant sources. Ferroelectric Materials for Energy Harvesting and Storage is the first book to bring together fundamental mechanisms for harvesting various abundant energy sources using ferroelectric and piezoelectric materials. The authors discuss strategies of designing materials for efficiently harvesting energy sources like solar, wind, wave, temperature fluctuations, mechanical vibrations, biomechanical motion, and stray magnetic fields. In addition, concepts of the high density energy storage using ferroelectric materials is explored. Ferroelectric Materials for Energy Harvesting and Storage is appropriate for those working in materials science and engineering, physics, chemistry and electrical engineering disciplines.

- Reviews wide range of energy harvesting including solar, wind, biomechanical and more
- Discusses ferroelectric materials and their application to high energy density capacitors
- Includes review of fundamental mechanisms of energy harvesting and energy solutions, their design and current applications, and future trends and challenges
  • Englisch
  • Cambridge
  • |
  • Großbritannien
Elsevier Science & Technology
  • Für Beruf und Forschung
  • |
  • Materials Scientists and Engineers, Electrical Engineers, Physicists, Researchers in both academia and R&D
Approx. 200 illustrations (80 in full color)
  • Höhe: 229 mm
  • |
  • Breite: 152 mm
978-0-08-102802-5 (9780081028025)
Deepam Maurya is a Research Assistant Professor at Virginia Tech. He received his PhD degree in materials science and engineering from Virginia Tech in December 2012. Dr. Maurya's research interest includes ferroelectric/piezoelectric materials and devices, multiferroic, piezoelectric energy harvesting, thermoelectric materials, 3-D printing and laser annealing, high k dielectric materials. Working on various research projects, Maurya has significantly contributed to the field of electro-ceramics through 62 research papers. Maurya contributed 5 book chapters and have 13 papers in refereed conference proceedings. He delivered 15 invited talks and contributed 34 presentations in conferences/seminars. Maurya served as a session chair in symposia at several international conferences. Abhijit Pramanick is an Assistant Professor at the City University of Hong Kong. He obtained his Bachelors in Engineering from the National Institute of Technology, Rourkela, India and his Masters in Engineering from the Indian Institute of Science, Bangalore. He was awarded PhD in Materials Science and Engineering in 2009 from the University of Florida, Gainesville. After his PhD, he spent one year as a postdoctoral researcher at the ceramics laboratory of the Alfred University in New York, USA. Subsequently, he moved to the Oak Ridge National Laboratory, where he spent three and half years working on the applications of different neutron scattering techniques to understand the microscopic origins of functional responses in ferroelectric and ferromagnetic materials. He has co-authored over 30 publications. For his work on ferroelectric ceramics, he was awarded the prestigious Edward C. Henry Award by the American Ceramic Society in the years 2010 and 2012. His current research interests include understanding composition-structure-property correlations in ferroelectric ceramic and polymeric materials that are used in smart technologies and energy applications using advanced neutron and X-ray scattering techniques. Dwight Viehland, Jack E. Cowling Professor of Engineering, Virginia Tech, Virginia, USA
1. Introduction (Fundamentals of ferroelectric/piezoelectric materials)
2. Solar energy harvesting with ferroelectric materials
3. Harvesting thermal energy with ferroelectric materials
4. Harvesting stray vibrations using piezoelectric materials
5. Wave flow energy harvesting with piezoelectric materials
6. Wind energy harvesting with piezoelectric materials
7. Biomechanical energy harvesting with piezoelectric materials
8. Harvesting stray magnetic field for powering wireless sensors
9. High energy density capacitors for energy storage
10. Future directions and outlook

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