期刊
OPTICS EXPRESS
卷 29, 期 11, 页码 16284-16298出版社
Optica Publishing Group
DOI: 10.1364/OE.424983
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资金
- Ministry of Science and Technology, Taiwan [109-2112-M-005-005]
The study introduces a novel all-dielectric waveguide structure that achieves mode areas comparable to plasmonic waveguides and theoretical lossless by exploiting the electromagnetic boundary conditions at a high-index-contrast interface.
Plasmonic waveguides can offer a promising solution beyond the optical diffraction limit. However, the cost of shrinking mode sizes reflects in metallic ohmic losses that lead to a short propagation distance of light, hindering the practical applications of plasmonic waveguides. Herein, we tackled the practicality of a novel CMOS-compatible all-dielectric waveguide structure that exploits electromagnetic boundary conditions of both the continuous normal component of the electric displacement field and the tangential component of the electric field at a high-index-contrast interface, which allows the attainment of mode areas comparable with those of plasmonic waveguides and theoretical lossless. The proposed waveguide comprises two oppositely contacted nanoridges with semicircular tops embedded in a conventional slot waveguide. By stepping on the strong electric field in the low-index slot region of the slot waveguides, the nanoridges squeeze the mode areas further with a guiding mechanism identical to that of a surrounding slot waveguide. Through the design of the geometry parameters, the calculated mode area of the reported structure achieved an unprecedented order of 4.21 x 10(-5) A(0), where A(0) is the diffraction-limited area. The mode area dependence on fabrication imperfections and spectral response showed the robustness and broadband operation. Moreover, on the basis of extremely tight mode confinements, the present waveguide even outperformed the hybrid plasmonic waveguides in lower crosstalk. The proposed idea makes the realization of practically feasible nanoscale photonic integrated circuits without any obstructions by the limited propagation distance of light for plasmonic waveguides, thereby expanding its applications in various nanophotonic and optoelectronics devices requiring strong light-matter interaction within nanoscale regions. (C) 2021 Optical Society of America under the terms of the OSA Open Access Publishing Agreement
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