A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device
Nowadays, low-frequency electromagnetic interference (<2.0 GHz) remains a key core issue that plagues the effective attenuation performance of conventional absorption devices prepared via the component-morphology method (Strategy I). According to theoretical calculations, one fundamental solution...
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sg-ntu-dr.10356-1389442020-06-01T10:26:49Z A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device Lv, Hualiang Yang, Zhihong Wang, Paul Luyuan Ji, Guangbin Song, Jizhong Zheng, Lirong Zeng, Haibo Xu, Zhichuan Jason School of Materials Science & Engineering Engineering::Materials Electromagnetic Wave Absorption Flexible Electronics Nowadays, low-frequency electromagnetic interference (<2.0 GHz) remains a key core issue that plagues the effective attenuation performance of conventional absorption devices prepared via the component-morphology method (Strategy I). According to theoretical calculations, one fundamental solution is to develop a material that possesses a high ε' but lower ε″. Thus, it is attempted to control the dielectric values via applying an external electrical field, which inducts changes in the macrostructure toward a performance improvement (Strategy II). A sandwich-structured flexible electronic absorption device is designed using a carbon film electrode to conduct an external current. Simultaneously, an absorption layer that is highly responsive to an external voltage is selected via Strategy I. Relying on the synergistic effects from Strategies I and II, this device demonstrates an absorption value of more than 85% at 1.5-2.0 GHz with an applied voltage of 16 V while reducing the thickness to ≈5 mm. In addition, the device also shows a good absorption property at 25-150 °C. The method of utilizing an external voltage to break the intrinsic dielectric feature by modifying a traditional electronic absorption device is demonstrated for the first time and has great significance in solving the low-frequency electromagnetic interference issue. 2020-05-14T04:40:48Z 2020-05-14T04:40:48Z 2018 Journal Article Lv, H., Yang, Z., Wang, P. L., Ji, G., Song, J., Zheng, L., . . . Xu, Z. J. (2018). A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device. Advanced Materials, 30(15), 1706343-. doi:10.1002/adma.201706343 0935-9648 https://hdl.handle.net/10356/138944 10.1002/adma.201706343 29512210 2-s2.0-85042418860 15 30 en Advanced Materials © 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. All rights reserved. This paper was published in Advanced Materials and is made available with permission of WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim. |
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Engineering::Materials Electromagnetic Wave Absorption Flexible Electronics |
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Engineering::Materials Electromagnetic Wave Absorption Flexible Electronics Lv, Hualiang Yang, Zhihong Wang, Paul Luyuan Ji, Guangbin Song, Jizhong Zheng, Lirong Zeng, Haibo Xu, Zhichuan Jason A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| description |
Nowadays, low-frequency electromagnetic interference (<2.0 GHz) remains a key core issue that plagues the effective attenuation performance of conventional absorption devices prepared via the component-morphology method (Strategy I). According to theoretical calculations, one fundamental solution is to develop a material that possesses a high ε' but lower ε″. Thus, it is attempted to control the dielectric values via applying an external electrical field, which inducts changes in the macrostructure toward a performance improvement (Strategy II). A sandwich-structured flexible electronic absorption device is designed using a carbon film electrode to conduct an external current. Simultaneously, an absorption layer that is highly responsive to an external voltage is selected via Strategy I. Relying on the synergistic effects from Strategies I and II, this device demonstrates an absorption value of more than 85% at 1.5-2.0 GHz with an applied voltage of 16 V while reducing the thickness to ≈5 mm. In addition, the device also shows a good absorption property at 25-150 °C. The method of utilizing an external voltage to break the intrinsic dielectric feature by modifying a traditional electronic absorption device is demonstrated for the first time and has great significance in solving the low-frequency electromagnetic interference issue. |
| author2 |
School of Materials Science & Engineering |
| author_facet |
School of Materials Science & Engineering Lv, Hualiang Yang, Zhihong Wang, Paul Luyuan Ji, Guangbin Song, Jizhong Zheng, Lirong Zeng, Haibo Xu, Zhichuan Jason |
| format |
Article |
| author |
Lv, Hualiang Yang, Zhihong Wang, Paul Luyuan Ji, Guangbin Song, Jizhong Zheng, Lirong Zeng, Haibo Xu, Zhichuan Jason |
| author_sort |
Lv, Hualiang |
| title |
A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| title_short |
A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| title_full |
A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| title_fullStr |
A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| title_full_unstemmed |
A voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| title_sort |
voltage-boosting strategy enabling a low-frequency, flexible electromagnetic wave absorption device |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/138944 |
| _version_ |
1681058912568082432 |