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Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices
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Zeitschriftentitel: | Sensors |
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Personen und Körperschaften: | , |
In: | Sensors, 20, 2020, 14, S. 3872 |
Format: | E-Article |
Sprache: | Englisch |
veröffentlicht: |
MDPI AG
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Schlagwörter: |
author_facet |
Oh, Hongseok Dayeh, Shadi A. Oh, Hongseok Dayeh, Shadi A. |
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author |
Oh, Hongseok Dayeh, Shadi A. |
spellingShingle |
Oh, Hongseok Dayeh, Shadi A. Sensors Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices Electrical and Electronic Engineering Biochemistry Instrumentation Atomic and Molecular Physics, and Optics Analytical Chemistry |
author_sort |
oh, hongseok |
spelling |
Oh, Hongseok Dayeh, Shadi A. 1424-8220 MDPI AG Electrical and Electronic Engineering Biochemistry Instrumentation Atomic and Molecular Physics, and Optics Analytical Chemistry http://dx.doi.org/10.3390/s20143872 <jats:p>Piezoelectric devices transduce mechanical energy to electrical energy by elastic deformation, which distorts local dipoles in crystalline materials. Amongst electromechanical sensors, piezoelectric devices are advantageous because of their scalability, light weight, low power consumption, and readily built-in amplification and ability for multiplexing, which are essential for wearables, medical devices, and robotics. This paper reviews recent progress in active piezoelectric devices. We classify these piezoelectric devices according to the material dimensionality and present physics-based device models to describe and quantify the piezoelectric response for one-dimensional nanowires, emerging two-dimensional materials, and three-dimensional thin films. Different transduction mechanisms and state-of-the-art devices for each type of material are reviewed. Perspectives on the future applications of active piezoelectric devices are discussed.</jats:p> Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices Sensors |
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title |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_unstemmed |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_full |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_fullStr |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_full_unstemmed |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_short |
Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_sort |
physics-based device models and progress review for active piezoelectric semiconductor devices |
topic |
Electrical and Electronic Engineering Biochemistry Instrumentation Atomic and Molecular Physics, and Optics Analytical Chemistry |
url |
http://dx.doi.org/10.3390/s20143872 |
publishDate |
2020 |
physical |
3872 |
description |
<jats:p>Piezoelectric devices transduce mechanical energy to electrical energy by elastic deformation, which distorts local dipoles in crystalline materials. Amongst electromechanical sensors, piezoelectric devices are advantageous because of their scalability, light weight, low power consumption, and readily built-in amplification and ability for multiplexing, which are essential for wearables, medical devices, and robotics. This paper reviews recent progress in active piezoelectric devices. We classify these piezoelectric devices according to the material dimensionality and present physics-based device models to describe and quantify the piezoelectric response for one-dimensional nanowires, emerging two-dimensional materials, and three-dimensional thin films. Different transduction mechanisms and state-of-the-art devices for each type of material are reviewed. Perspectives on the future applications of active piezoelectric devices are discussed.</jats:p> |
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author | Oh, Hongseok, Dayeh, Shadi A. |
author_facet | Oh, Hongseok, Dayeh, Shadi A., Oh, Hongseok, Dayeh, Shadi A. |
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container_title | Sensors |
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description | <jats:p>Piezoelectric devices transduce mechanical energy to electrical energy by elastic deformation, which distorts local dipoles in crystalline materials. Amongst electromechanical sensors, piezoelectric devices are advantageous because of their scalability, light weight, low power consumption, and readily built-in amplification and ability for multiplexing, which are essential for wearables, medical devices, and robotics. This paper reviews recent progress in active piezoelectric devices. We classify these piezoelectric devices according to the material dimensionality and present physics-based device models to describe and quantify the piezoelectric response for one-dimensional nanowires, emerging two-dimensional materials, and three-dimensional thin films. Different transduction mechanisms and state-of-the-art devices for each type of material are reviewed. Perspectives on the future applications of active piezoelectric devices are discussed.</jats:p> |
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physical | 3872 |
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publisher | MDPI AG |
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spelling | Oh, Hongseok Dayeh, Shadi A. 1424-8220 MDPI AG Electrical and Electronic Engineering Biochemistry Instrumentation Atomic and Molecular Physics, and Optics Analytical Chemistry http://dx.doi.org/10.3390/s20143872 <jats:p>Piezoelectric devices transduce mechanical energy to electrical energy by elastic deformation, which distorts local dipoles in crystalline materials. Amongst electromechanical sensors, piezoelectric devices are advantageous because of their scalability, light weight, low power consumption, and readily built-in amplification and ability for multiplexing, which are essential for wearables, medical devices, and robotics. This paper reviews recent progress in active piezoelectric devices. We classify these piezoelectric devices according to the material dimensionality and present physics-based device models to describe and quantify the piezoelectric response for one-dimensional nanowires, emerging two-dimensional materials, and three-dimensional thin films. Different transduction mechanisms and state-of-the-art devices for each type of material are reviewed. Perspectives on the future applications of active piezoelectric devices are discussed.</jats:p> Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices Sensors |
spellingShingle | Oh, Hongseok, Dayeh, Shadi A., Sensors, Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices, Electrical and Electronic Engineering, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Analytical Chemistry |
title | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_full | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_fullStr | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_full_unstemmed | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_short | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
title_sort | physics-based device models and progress review for active piezoelectric semiconductor devices |
title_unstemmed | Physics-Based Device Models and Progress Review for Active Piezoelectric Semiconductor Devices |
topic | Electrical and Electronic Engineering, Biochemistry, Instrumentation, Atomic and Molecular Physics, and Optics, Analytical Chemistry |
url | http://dx.doi.org/10.3390/s20143872 |