Silicon-Based Plasmonics for On-Chip Photonics

Dionne, Jennifer A.; Sweatlock, Luke A.; Sheldon, Matthew; Alivisatos, A. Paul; Atwater, Harry A.

doi:10.1109/jstqe.2009.2034983

Cited by 147 publications

(88 citation statements)

References 80 publications

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“…Like photonic circuits, plasmonic circuits promise higher bandwidth, higher speed, lower latency, and reduced power consumption than electronic circuits. 55 Plasmonic circuits also promise miniaturization of photonic circuits-with deeply subwavelength dimensions and dense component integration commensurate with electronic circuits. Such an integrated plasmonic technology could revolutionize the speed, size, cost, and power requirements of modern computational networks, provided key challenges such as loss and inter-device coupling can be addressed.…”

Section: Passive and Active Plasmonic Devicesmentioning

confidence: 99%

Plasmonics: Metal-worthy methods and materials in nanophotonics

Dionne

Atwater

2012

MRS Bull.

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Electrons and photons can coexist as a single entity called a surface plasmon-an elementary excitation found at the interface between a conductor and an insulator. Because of their hybrid electric and photonic nature, plasmons allow photons to be precisely controlled on the nanoscale. Plasmons are evident in the vivid hues of rose windows, which derive their color from small metallic nanoparticles embedded in the glass. They also provide the basis for color-changing biosensors (such as home pregnancy tests), photothermal cancer treatments, improved photovoltaic cell effi ciencies, and nanoscale lasers. While surface plasmons were fi rst identifi ed nearly 55 years ago, many of their exciting applications are yet to come. This issue of MRS Bulletin reviews the progress and promise of plasmonics-from the characterization tools that have allowed nanometer-scale probing of plasmons to the new materials that may enable low-loss, active, and quantum plasmonics. Within reach are applications ranging from integrated plasmonic circuits for nanophotonic computation to plasmonic optical tweezers for manipulation of nano-sized particles and proteins.

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Section: Passive and Active Plasmonic Devicesmentioning

confidence: 99%

Plasmonics: Metal-worthy methods and materials in nanophotonics

Dionne

Atwater

2012

MRS Bull.

Self Cite

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“…68 One possible integrated optoelectronic circuit design is illustrated in Figure 5 a, including an artist's depiction of nanophotonic sources, waveguides, modulators, diodes, fi lters, and photodetectors. 69 Localized surface plasmons are critical to many of these components.…”

Section: Modulators and Lasersmentioning

confidence: 99%

Localized fields, global impact: Industrial applications of resonant plasmonic materials

et al. 2015

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“…Ideally, emerging chip-scale technologies would enable monolithic integration of electronic, photonic, and nanoplasmonic waveguide devices [3][4][5][6][7][8][9]. In such a scheme, electronic devices would continue to perform their typical functionality, photonic waveguides would be used for low-loss, high-bandwidth signal transmission and multiplexing/demultiplexing of narrowband signals, and nanoplasmonic waveguides would be used for bridging the dimensional gap between photonic and electronic devices, high-density optical circuitry, as well as efficient nonlinear and magnetoplasmonic devices.…”

Section: Introductionmentioning

confidence: 99%

Integrated nanoplasmonic waveguides for magnetic, nonlinear, and strong-field devices

et al. 2016

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Abstract: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 stateof-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.

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Silicon-Based Plasmonics for On-Chip Photonics

Cited by 147 publications

References 80 publications

Plasmonics: Metal-worthy methods and materials in nanophotonics

Plasmonics: Metal-worthy methods and materials in nanophotonics

Localized fields, global impact: Industrial applications of resonant plasmonic materials

Integrated nanoplasmonic waveguides for magnetic, nonlinear, and strong-field devices

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