Passive plasmonic waveguide-based devices

Er-Ping Li; Hong-Son Chu

doi:10.1017/CBO9781139208802.006

5 - Passive plasmonic waveguide-based devices

Published online by Cambridge University Press: 05 March 2014

Er-Ping Li and

Hong-Son Chu

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Er-Ping Li: Affiliation:
A*STAR Institute of High Performance Computing, Singapore
Hong-Son Chu: Affiliation:
A*STAR Institute of High Performance Computing, Singapore

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Summary

This chapter presents the hybrid plasmonic waveguide (HPW) platform and its components. In particular, the effective mode index, propagation distance, and mode confinement of the planar vertical hybrid plasmonic waveguides (VHPWs) are numerically characterized as functions of dimensions and materials in the near-infrared wavelengths. The chapter demonstrates that the vertical hybrid silver–silica–silicon plasmonic waveguide achieves better propagation characteristics than those of the counterpart silver–silica–silver MIM and silicon-based dielectric-loaded plasmonic waveguide. Moreover, we propose and design various passive waveguide-based components based on the optimized VHPW, including bends, power-splitters, couplers, and ring resonator filters. An important issue is how to implement these HPW-based components and devices in standard complementary metal–oxide–semiconductor (CMOS) electronic–photonic integrated circuits. To meet this requirement, two CMOS-compatible HPW platforms, namely a copper-cap VHPW and a hybrid horizontal copper–silicon dioxide–siliconsilicon dioxide–copper plasmonic waveguide, and devices based on them such as bends and ring resonator filters are subjected to further investigation both in experiments and in theory in the subsequent sections.

Introduction

In the context of communications and information processing, integration of photonic and nanoelectronic devices on the same chip would lead to a tremendous synergy by combining the ultra-compactness of nanoelectronics with the super-wide bandwidth of photonics. Such integration will benefit considerably from the application of nanotechnology for data-processing, sensing, medical, health-care, and energy purposes. In recent years, it has been demonstrated theoretically and experimentally that plasmonic devices, taking advantage of plasmon-enabled tight modal confinement, promise to overcome the size mismatch between microscale photonics and nanoscale electronics.

Type: Chapter
Information: Plasmonic Nanoelectronics and Sensing , pp. 139 - 179

DOI: https://doi.org/10.1017/CBO9781139208802.006 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2014

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