$Plasmonic Titanium Nitride Nanohole Arrays for Refractometric Sensing$

Plasmonic Titanium Nitride Nanohole Arrays for Refractometric Sensing

Group IVB metal nitrides have attracted great interest as alternative plasmonic materials. Among them, titanium nitride (TiN) stands out due to the ease of deposition and relative abundance of Ti compared to those of Zr and Hf metals. Even though they do not have Au or Ag-like plasmonic characterist...

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Veröffentlicht in:	ACS applied nano materials 2023-11, Vol.6 (22), p.20612-20622
Hauptverfasser:	Günaydın, Beyza Nur, Gülmez, Mert, Torabfam, Milad, Pehlivan, Zeki Semih, Tütüncüoğlu, Atacan, Kayalan, Cemre Irmak, Saatçioğlu, Erhan, Bayazıt, Mustafa Kemal, Yüce, Meral, Kurt, Hasan
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creator	Günaydın, Beyza Nur Gülmez, Mert Torabfam, Milad Pehlivan, Zeki Semih Tütüncüoğlu, Atacan Kayalan, Cemre Irmak Saatçioğlu, Erhan Bayazıt, Mustafa Kemal Yüce, Meral Kurt, Hasan
description	Group IVB metal nitrides have attracted great interest as alternative plasmonic materials. Among them, titanium nitride (TiN) stands out due to the ease of deposition and relative abundance of Ti compared to those of Zr and Hf metals. Even though they do not have Au or Ag-like plasmonic characteristics, they offer many advantages, from high mechanical stability to refractory behavior and complementary metal oxide semiconductor-compatible fabrication to tunable electrical/optical properties. In this study, we utilized reactive RF magnetron sputtering to deposit plasmonic TiN thin films. The flow rate and ratio of Ar/N2 and oxygen scavenging methods were optimized to improve the plasmonic performance of TiN thin films. The stoichiometry and structure of the TiN thin films were thoroughly investigated to assess the viability of the optimized operation procedures. To assess the plasmonic performance of TiN thin films, periodic nanohole arrays were perforated on TiN thin films by using electron beam lithography and reactive ion etching methods. The resulting TiN periodic nanohole array with varying periods was investigated by using a custom microspectroscopy setup for both reflection and transmission characteristics in various media to underline the efficacy of TiN for refractometric sensing.
doi_str_mv	10.1021/acsanm.3c03050
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Among them, titanium nitride (TiN) stands out due to the ease of deposition and relative abundance of Ti compared to those of Zr and Hf metals. Even though they do not have Au or Ag-like plasmonic characteristics, they offer many advantages, from high mechanical stability to refractory behavior and complementary metal oxide semiconductor-compatible fabrication to tunable electrical/optical properties. In this study, we utilized reactive RF magnetron sputtering to deposit plasmonic TiN thin films. The flow rate and ratio of Ar/N2 and oxygen scavenging methods were optimized to improve the plasmonic performance of TiN thin films. The stoichiometry and structure of the TiN thin films were thoroughly investigated to assess the viability of the optimized operation procedures. To assess the plasmonic performance of TiN thin films, periodic nanohole arrays were perforated on TiN thin films by using electron beam lithography and reactive ion etching methods. 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title	Plasmonic Titanium Nitride Nanohole Arrays for Refractometric Sensing
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