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High Fluence Chromium and Tungsten Bowtie Nano-antennas

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Authors

Morshed, Monir
Li, Ziyuan
Olbricht, Benjamin C
Fu, Lan
Haque, Ahasanul
Li, Li (Lily)
Aoni, Rifat Ahmmed
Rahmani, Mohsen
Miroshnichenko, Andrey
Hattori, Haroldo

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Nature Publishing Group

Abstract

Nano-antennas are replicas of antennas that operate at radio-frequencies, but with considerably smaller dimensions when compared with their radio frequency counterparts. Noble metals based nano-antennas have the ability to enhance photoinduced phenomena such as localized electric fields, therefore-they have been used in various applications ranging from optical sensing and imaging to performance improvement of solar cells. However, such nano-structures can be damaged in high power applications such as heat resisted magnetic recording, solar thermo-photovoltaics and nano-scale heat transfer systems. Having a small footprint, nano-antennas cannot handle high fluences (energy density per unit area) and are subject to being damaged at adequately high power (some antennas can handle just a few milliwatts). In addition, given that nano-antennas are passive devices driven by external light sources, the potential damage of the antennas limits their use with high power lasers: this liability can be overcome by employing materials with high melting points such as chromium (Cr) and tungsten (W). In this article, we fabricate chromium and tungsten nano-antennas and demonstrate that they can handle 110 and 300 times higher fluence than that of gold (Au) counterpart, while the electric field enhancement is not significantly reduced.

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Source

Scientific Reports

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Open Access

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Creative Commons Attribution 4.0 International License

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