Light absorption and nanofocusing on a tapered magnetic metasurface

A type of metasurface was constructed on a silicon wafer using a nanopatterned magnetic film to achieve ideal light absorption within a wide wavelength range of 3 μm–15 μm. Using the metasurface, the surface electrons could be localized efficiently into an arrayed planar magnetic nanotip and then mo...

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Published in	Applied physics letters Vol. 117; no. 24
Main Authors	Wei, Dong, Hu, Chai, Chen, Mingce, Shi, Jiashuo, Luo, Jun, Wang, Haiwei, Xie, Changsheng, Zhang, Xinyu
Format	Journal Article
Language	English
Published	Melville American Institute of Physics 14.12.2020
Subjects	Aluminum Applied physics Arrays Electric fields Electromagnetic absorption Infrared analysis Magnetic films Metasurfaces Reflectance Silicon wafers Surface chemistry
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Abstract	A type of metasurface was constructed on a silicon wafer using a nanopatterned magnetic film to achieve ideal light absorption within a wide wavelength range of 3 μm–15 μm. Using the metasurface, the surface electrons could be localized efficiently into an arrayed planar magnetic nanotip and then modulated by configuring the surface architecture to produce remarkable infrared reflectivity variation. A theoretical analysis showed that the excited surface plasmon exhibit stronger electric field components at the common metal-to-air interface. The Tb14Fe68Co18 nanotip array provided more powerful nanofocusing and a lower infrared reflectivity than an array shaped on a traditional aluminum film. By adjusting the structural parameters of the nanorhombus array formed on the TbCo film system, the convergent light spot could be modulated to improve light absorption markedly.
AbstractList	A type of metasurface was constructed on a silicon wafer using a nanopatterned magnetic film to achieve ideal light absorption within a wide wavelength range of 3 μm–15 μm. Using the metasurface, the surface electrons could be localized efficiently into an arrayed planar magnetic nanotip and then modulated by configuring the surface architecture to produce remarkable infrared reflectivity variation. A theoretical analysis showed that the excited surface plasmon exhibit stronger electric field components at the common metal-to-air interface. The Tb14Fe68Co18 nanotip array provided more powerful nanofocusing and a lower infrared reflectivity than an array shaped on a traditional aluminum film. By adjusting the structural parameters of the nanorhombus array formed on the TbCo film system, the convergent light spot could be modulated to improve light absorption markedly.
Author	Luo, Jun Zhang, Xinyu Shi, Jiashuo Chen, Mingce Hu, Chai Wei, Dong Wang, Haiwei Xie, Changsheng
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SubjectTerms	Aluminum Applied physics Arrays Electric fields Electromagnetic absorption Infrared analysis Magnetic films Metasurfaces Reflectance Silicon wafers Surface chemistry
Title	Light absorption and nanofocusing on a tapered magnetic metasurface
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