期刊论文详细信息
Nanophotonics
Integrated nanoplasmonic waveguides for magnetic, nonlinear, and strong-field devices
article
Shawn Sederberg1  Curtis J. Firby1  Shawn R. Greig1  Abdulhakem Y. Elezzabi1 
[1] University of Alberta, Ultrafast Optics and Nanophotonics Research Laboratory
关键词: nanoplasmonics;    waveguides;    integrated optics;    ultrafast optics;    nonlinear optics;    magnetoplasmonics;    strong field phenomena;   
DOI  :  10.1515/nanoph-2016-0135
学科分类:社会科学、人文和艺术(综合)
来源: De Gruyter
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【 摘 要 】

As modern complementary-metal-oxide-semiconductor (CMOS) circuitry rapidly approaches fundamental speed and bandwidth limitations, optical platforms have become promising candidates to circumvent these limits and facilitate massive increases in computational power. To compete with high density CMOS circuitry, optical technology within the plasmonic regime is desirable, because of the sub-diffraction limited confinement of electromagnetic energy, large optical bandwidth, and ultrafast processing capabilities. As such, nanoplasmonic waveguides act as nanoscale conduits for optical signals, thereby forming the backbone of such a platform. In recent years, significant research interest has developed to uncover the fundamental physics governing phenomena occurring within nanoplasmonic waveguides, and to implement unique optical devices. In doing so, a wide variety of material properties have been exploited. CMOS-compatible materials facilitate passive plasmonic routing devices for directing the confined radiation. Magnetic materials facilitate time-reversal symmetry breaking, aiding in the development of nonreciprocal isolators or modulators. Additionally, strong confinement and enhancement of electric fields within such waveguides require the use of materials with high nonlinear coefficients to achieve increased nonlinear optical phenomenon in a nanoscale footprint. Furthermore, this enhancement and confinement of the fields facilitate the study of strong-field effects within the solid-state environment of the waveguide. Here, we review current state-of-the-art physics and applications of nanoplasmonic waveguides pertaining to passive, magnetoplasmonic, nonlinear, and strong-field devices. Such components are essential elements in integrated optical circuitry, and each fulfill specific roles in truly developing a chip-scale plasmonic computing architecture.

【 授权许可】

CC BY   

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