Piezoelectric potential in single-crystalline ZnO nanohelices based on finite element analysis

Huimin Hao; Kory Jenkins; Xiaowen Huang; Yiqian Xu; Jiahai Huang; Rusen Yang

doi:10.3390/nano7120430

Piezoelectric potential in single-crystalline ZnO nanohelices based on finite element analysis

Huimin Hao, Kory Jenkins, Xiaowen Huang, Yiqian Xu, Jiahai Huang, Rusen Yang

Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

17 Scopus citations

Abstract

Electric potential produced in deformed piezoelectric nanostructures is of significance for both fundamental study and practical applications. To reveal the piezoelectric property of ZnO nanohelices, the piezoelectric potential in single-crystal nanohelices was simulated by finite element method calculations. For a nanohelix with a length of 1200 nm, a mean coil radius of 150 nm, five active coils, and a hexagonal coiled wire with a side length 100 nm, a compressing force of 100 nN results in a potential of 1.85 V. This potential is significantly higher than the potential produced in a straight nanowire with the same length and applied force. Maintaining the length and increasing the number of coils or mean coil radius leads to higher piezoelectric potential in the nanohelix. Appling a force along the axial direction produces higher piezoelectric potential than in other directions. Adding lateral forces to an existing axial force can change the piezoelectric potential distribution in the nanohelix, while the maximum piezoelectric potential remains largely unchanged in some cases. This research demonstrates the promising potential of ZnO nanohelices for applications in sensors, micro-electromechanical systems (MEMS) devices, nanorobotics, and energy sciences.

Original language	English (US)
Article number	430
Journal	Nanomaterials
Volume	7
Issue number	12
DOIs	https://doi.org/10.3390/nano7120430
State	Published - Dec 7 2017

Bibliographical note

Funding Information:
The authors are grateful for financial support from the Department of Mechanical Engineering and the College of Science and Engineering of the University of Minnesota. Research is supported in part by NSF (ECCS-1150147) and by NSF IGERT grant DGE-1069104. This work was also supported by Shanxi Province Key Research and Development Program (International Cooperation) (Grant No. 201603D421009).

Funding Information:
Acknowledgments: The authors are grateful for financial support from the Department of Mechanical Engineering and the College of Science and Engineering of the University of Minnesota. Research is supported in part by NSF (ECCS-1150147) and by NSF IGERT grant DGE-1069104. This work was also supported by Shanxi Province Key Research and Development Program (International Cooperation) (Grant No. 201603D421009).

Publisher Copyright:
© 2017 by the authors. Licensee MDPI, Basel, Switzerland.

Keywords

FEM
Nanohelix
Numerical simulation
Piezotronic

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10.3390/nano7120430

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abstract = "Electric potential produced in deformed piezoelectric nanostructures is of significance for both fundamental study and practical applications. To reveal the piezoelectric property of ZnO nanohelices, the piezoelectric potential in single-crystal nanohelices was simulated by finite element method calculations. For a nanohelix with a length of 1200 nm, a mean coil radius of 150 nm, five active coils, and a hexagonal coiled wire with a side length 100 nm, a compressing force of 100 nN results in a potential of 1.85 V. This potential is significantly higher than the potential produced in a straight nanowire with the same length and applied force. Maintaining the length and increasing the number of coils or mean coil radius leads to higher piezoelectric potential in the nanohelix. Appling a force along the axial direction produces higher piezoelectric potential than in other directions. Adding lateral forces to an existing axial force can change the piezoelectric potential distribution in the nanohelix, while the maximum piezoelectric potential remains largely unchanged in some cases. This research demonstrates the promising potential of ZnO nanohelices for applications in sensors, micro-electromechanical systems (MEMS) devices, nanorobotics, and energy sciences.",

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AU - Yang, Rusen

N1 - Funding Information: The authors are grateful for financial support from the Department of Mechanical Engineering and the College of Science and Engineering of the University of Minnesota. Research is supported in part by NSF (ECCS-1150147) and by NSF IGERT grant DGE-1069104. This work was also supported by Shanxi Province Key Research and Development Program (International Cooperation) (Grant No. 201603D421009). Funding Information: Acknowledgments: The authors are grateful for financial support from the Department of Mechanical Engineering and the College of Science and Engineering of the University of Minnesota. Research is supported in part by NSF (ECCS-1150147) and by NSF IGERT grant DGE-1069104. This work was also supported by Shanxi Province Key Research and Development Program (International Cooperation) (Grant No. 201603D421009). Publisher Copyright: © 2017 by the authors. Licensee MDPI, Basel, Switzerland.

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N2 - Electric potential produced in deformed piezoelectric nanostructures is of significance for both fundamental study and practical applications. To reveal the piezoelectric property of ZnO nanohelices, the piezoelectric potential in single-crystal nanohelices was simulated by finite element method calculations. For a nanohelix with a length of 1200 nm, a mean coil radius of 150 nm, five active coils, and a hexagonal coiled wire with a side length 100 nm, a compressing force of 100 nN results in a potential of 1.85 V. This potential is significantly higher than the potential produced in a straight nanowire with the same length and applied force. Maintaining the length and increasing the number of coils or mean coil radius leads to higher piezoelectric potential in the nanohelix. Appling a force along the axial direction produces higher piezoelectric potential than in other directions. Adding lateral forces to an existing axial force can change the piezoelectric potential distribution in the nanohelix, while the maximum piezoelectric potential remains largely unchanged in some cases. This research demonstrates the promising potential of ZnO nanohelices for applications in sensors, micro-electromechanical systems (MEMS) devices, nanorobotics, and energy sciences.

AB - Electric potential produced in deformed piezoelectric nanostructures is of significance for both fundamental study and practical applications. To reveal the piezoelectric property of ZnO nanohelices, the piezoelectric potential in single-crystal nanohelices was simulated by finite element method calculations. For a nanohelix with a length of 1200 nm, a mean coil radius of 150 nm, five active coils, and a hexagonal coiled wire with a side length 100 nm, a compressing force of 100 nN results in a potential of 1.85 V. This potential is significantly higher than the potential produced in a straight nanowire with the same length and applied force. Maintaining the length and increasing the number of coils or mean coil radius leads to higher piezoelectric potential in the nanohelix. Appling a force along the axial direction produces higher piezoelectric potential than in other directions. Adding lateral forces to an existing axial force can change the piezoelectric potential distribution in the nanohelix, while the maximum piezoelectric potential remains largely unchanged in some cases. This research demonstrates the promising potential of ZnO nanohelices for applications in sensors, micro-electromechanical systems (MEMS) devices, nanorobotics, and energy sciences.

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Piezoelectric potential in single-crystalline ZnO nanohelices based on finite element analysis

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