Issue 7, 2022

Mid- and far-infrared localized surface plasmon resonances in chalcogen-hyperdoped silicon

Abstract

Plasmonic sensing in the infrared region employs the direct interaction of the vibrational fingerprints of molecules with the plasmonic resonances, creating surface-enhanced sensing platforms that are superior to traditional spectroscopy. However, the standard noble metals used for plasmonic resonances suffer from high radiative losses as well as fabrication challenges, such as tuning the spectral resonance positions into mid- to far-infrared regions, and the compatibility issue with the existing complementary metal–oxide-semiconductor (CMOS) manufacturing platform. Here, we demonstrate the occurrence of mid-infrared localized surface plasmon resonances (LSPR) in thin Si films hyperdoped with the known deep-level impurity tellurium. We show that the mid-infrared LSPR can be further enhanced and spectrally extended to the far-infrared range by fabricating two-dimensional arrays of micrometer-sized antennas in a Te-hyperdoped Si chip. Since Te-hyperdoped Si can also work as an infrared photodetector, we believe that our results will unlock the route toward the direct integration of plasmonic sensors with the on-chip CMOS platform, greatly advancing the possibility of mass manufacturing of high-performance plasmonic sensing systems.

Graphical abstract: Mid- and far-infrared localized surface plasmon resonances in chalcogen-hyperdoped silicon

Supplementary files

Article information

Article type
Paper
Submitted
03 Nov 2021
Accepted
01 Feb 2022
First published
02 Feb 2022

Nanoscale, 2022,14, 2826-2836

Mid- and far-infrared localized surface plasmon resonances in chalcogen-hyperdoped silicon

M. Wang, Y. Yu, S. Prucnal, Y. Berencén, M. S. Shaikh, L. Rebohle, M. B. Khan, V. Zviagin, R. Hübner, A. Pashkin, A. Erbe, Y. M. Georgiev, M. Grundmann, M. Helm, R. Kirchner and S. Zhou, Nanoscale, 2022, 14, 2826 DOI: 10.1039/D1NR07274A

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