A Review on Piezoelectric, Magnetostrictive, and Magnetoelectric Materials and Device Technologies for Energy Harvesting Applications

In the coming era of the internet of things (IoT), wireless sensor networks that monitor, detect, and gather data will play a crucial role in advancements in public safety, human healthcare, industrial automation, and energy management. Batteries are currently the power source of choice for operatin...

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Bibliographic Details
Published inAdvanced engineering materials Vol. 20; no. 5
Main Authors Narita, Fumio, Fox, Marina
Format Journal Article
LanguageEnglish
Published 01.05.2018
Subjects
Electromagnetic materials and structures
Energy harvesting
Multi‐scale mechanics and multi‐physics
Output voltage and power
Simulation and experiment
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Abstract In the coming era of the internet of things (IoT), wireless sensor networks that monitor, detect, and gather data will play a crucial role in advancements in public safety, human healthcare, industrial automation, and energy management. Batteries are currently the power source of choice for operating wireless network devices due to their ease of installation; however, they require periodic replacement due to capacity limitations. Within the scope of the IoT, battery maintenance of the trillion sensor nodes that may be implemented will be practically infeasible from environmental, resource, and labor cost perspectives. In considering individual self‐powered sensor nodes, the idea of harvesting energy from ambient vibrations, heat, and electromagnetic waves has recently triggered noticeable research interest in the academic community. This paper gives an overview of energy harvesting materials and systems. Three main categories are presented: piezoelectric ceramics/polymers, magnetostrictive alloys, and magnetoelectric (ME) multiferroic composites. State‐of‐the‐art harvesting materials and structures are presented with a focus on characterization, fabrication, modeling and simulation, and durability and reliability. Some perspectives and challenges for the future development of energy harvesting materials are also highlighted. Recent progress in piezoelectric ceramics/polymers, magnetostrictive alloys, and magnetoelectric (ME) multiferroic composites for energy harvesting applications is systematically summarized. A survey of the challenges in characterization, fabrication, modeling and simulation, and durability and reliability is presented.
AbstractList In the coming era of the internet of things (IoT), wireless sensor networks that monitor, detect, and gather data will play a crucial role in advancements in public safety, human healthcare, industrial automation, and energy management. Batteries are currently the power source of choice for operating wireless network devices due to their ease of installation; however, they require periodic replacement due to capacity limitations. Within the scope of the IoT, battery maintenance of the trillion sensor nodes that may be implemented will be practically infeasible from environmental, resource, and labor cost perspectives. In considering individual self‐powered sensor nodes, the idea of harvesting energy from ambient vibrations, heat, and electromagnetic waves has recently triggered noticeable research interest in the academic community. This paper gives an overview of energy harvesting materials and systems. Three main categories are presented: piezoelectric ceramics/polymers, magnetostrictive alloys, and magnetoelectric (ME) multiferroic composites. State‐of‐the‐art harvesting materials and structures are presented with a focus on characterization, fabrication, modeling and simulation, and durability and reliability. Some perspectives and challenges for the future development of energy harvesting materials are also highlighted. Recent progress in piezoelectric ceramics/polymers, magnetostrictive alloys, and magnetoelectric (ME) multiferroic composites for energy harvesting applications is systematically summarized. A survey of the challenges in characterization, fabrication, modeling and simulation, and durability and reliability is presented.
Author Fox, Marina
Narita, Fumio
Author_xml – sequence: 1
  givenname: Fumio
  orcidid: 0000-0002-0957-1948
  surname: Narita
  fullname: Narita, Fumio
  email: narita@material.tohoku.ac.jp
  organization: Department of Materials Processing, Graduate School of Engineering, Tohoku University
– sequence: 2
  givenname: Marina
  surname: Fox
  fullname: Fox, Marina
  organization: Department of Materials Science and Engineering, University of California
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Snippet In the coming era of the internet of things (IoT), wireless sensor networks that monitor, detect, and gather data will play a crucial role in advancements in...
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SubjectTerms Electromagnetic materials and structures
Energy harvesting
Multi‐scale mechanics and multi‐physics
Output voltage and power
Simulation and experiment
Title A Review on Piezoelectric, Magnetostrictive, and Magnetoelectric Materials and Device Technologies for Energy Harvesting Applications
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