Matteo Pancaldi, Ryan Freeman, Matthias Hudl, Mattias C. Hoffmann, Sergei Urazhdin, Paolo Vavassori, Stepfano Bonett
https://128.84.21.199/pdf/1711.05670.pdf
We developed a silicon-based, single-layer anti-reflection coating that suppresses the reflectivity of metals at near-infrared wavelengths, enabling optical probing of nano-scale structures embedded in highly reflective surroundings. Our design does not affect the interaction of terahertz (THz) radiation with these metallic structures that can be used to achieve THz near-field enhancement. We demonstrated the functionality of the design by calculating and measuring the reflectivity of both infrared and THz radiation from a silicon/gold double layer as a function of the silicon thickness. We also fabricated the unit cell of a THz meta-material, a dipole antenna comprising two 20-nm thick extended gold plates separated by a 2 µm gap, where the THz field is locally enhanced. We used the time-domain finite element method to demonstrate that such near-field enhancement is preserved in the presence of the anti-reflection coating. Finally, we performed magneto-optical Kerr effect on a single 3-nm thick, 1-µm wide magnetic wire placed in the gap of such a dipole antenna. The wire only occupies 2% of the area probed by the laser beam, but its magneto-optical response can be clearly detected. Our design paves the way for ultrafast time-resolved studies of strong THz-driven dynamics in nano-structures using table-top femtosecond near-infrared lasers.
© 2017 Optical Society of America under the terms of the OSA Open Access Publishing Agreement
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