All-in-one, all-optical logic gates using liquid metal plasmon nonlinearity

Xu, Jinlong; Zhang, Chi; Wang, Yulin; Wang, Mudong; Xu, Yanming; Wei, Tianqi; Xie, Zhenda; Liu, Shiqiang; Lee, Chao-Kuei; Hu, Xiaopeng; Zhao, Gang; Lv, Xinjie; Zhang, Han; Zhu, Shining; Zhou, Lin

doi:10.1038/s41467-024-46014-3

Cited by 6 publications

(1 citation statement)

References 61 publications

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“…Surface plasmon polaritons (SPPs) are electromagnetic modes that arise at the metaldielectric interface through the interaction of free electrons and photons [1]. Thanks to their ability to transcend the diffraction limit and possess robust local field enhancement properties, SPPs offer immense potential for applications in nanoscale optical information transmission and processing [2], ultra-sensitive biological detection [3], sensing [4], and novel light sources [5].…”

Section: Introductionmentioning

confidence: 99%

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Yu,

Liu,

Xue

2024

Photonics

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A kind of surface plasmon waveguide composed of two nested cylindrical dielectric parallel nanowire pairs coated with graphene was designed and studied. The dependence of the mode characteristics and the normalized gradient force of the lowest two modes supported by the waveguide on the parameters involved were analyzed by using the multipole method. To ensure rigor, the finite element method was employed to verify the accuracy of the multipole method, thus confirming its results. The results show that the multipole method is a powerful tool for handling this type of waveguide. The real part of the effective refractive index, the propagation length, the figure of merit, and the normalized gradient force can be significantly affected by the operating wavelength, the Fermi energy of graphene, the waveguide geometric parameters, and the refractive index of the inner dielectric nanowire. Due to the employment of nested dielectric nanowire pairs coated with graphene, this waveguide structure exhibits significant gradient force that surpasses 100 nN·μm−1·mW−1. The observed phenomena can be attributed to the interaction of the field with graphene. This waveguide holds promising potential for applications in micro/nano integration, optical tweezers, and sensing technologies.

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Section: Introductionmentioning

confidence: 99%

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Yu,

Liu,

Xue

2024

Photonics

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Ultra Low Power Consumption Optoelectronic Logic Operation of CuO/BaTiO₃ Heterojunction Photodetector with Tunable Internal Electric Field Based on Poling Effect

Cho,

Choi,

Park

et al. 2024

Adv Materials Technologies

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The study presents a novel self‐powered ultraviolet (UV) photodetector harnessing both polarization fields and photovoltaic effects, enabling the realization of ultra‐low power, reconfigurable optoelectronic logic gates. The approach is demonstrated on a CuO/BaTiO3 heterojunction photodetector. The behavior of the photodetector is augmented by the poling effect, aligning the internal electric field of the BaTiO3 through the application of a robust external electric field, thereby facilitating the implementation of optoelectronic logic gates. In the unpoled state, the “XOR” and “OR” logic gates operated at voltages of 750 and −500 µV, respectively. However, upon poling up state, the “XOR” logic gate exhibits reduced operation voltage, operating at 500 µV, while the “OR” logic gate implements clarity at −500 µV. In the unpoled state the “AND” logic gate does not operate; however, upon poling in the downward direction, it operated at −500 µV. The achievement demonstrates successful ultra‐low‐power logic operations, utilizing voltages in the hundreds of micron scale, under a 310 nm wavelength and a light intensity of 0.52 mW·cm−2. Furthermore, controllable polarization electric fields in BaTiO3 enable the operation of “AND” logic gate in the unpoled state, presenting a promising avenue for future research in optoelectronic logic gate design.

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Photonic Spin‐Hall Logic Devices Based on Programmable Spoof Plasmonic Metamaterial

Jiang,

Li,

et al. 2024

Laser & Photonics Reviews

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The entanglement of the momentum of light with its spin at interfaces or inside structured media, known as the photonic spin‐Hall effect, holds great promise for various applications, such as beam splitting, focusing, and polarization detection. However, the photonic spin‐Hall effect remains unexplored in the field of logic operation. In this work, the photonic spin‐Hall effect of spoof surface plasmon polaritons (SSPPs) in programmable metamaterial is demonstrated. Moreover, photonic spin‐Hall logic devices based on programmable spoof plasmonic metamaterial are designed, enabling the control of energy flow through the utilization of both spin and digital coding, with examples including SSPPs logic gates such as the “AND” gate, the “NIMPLY” gate (A AND NOT B), the “OR” gate, and the “NOT” gate. The findings introduce the combination of digital coding metamaterial with the photonic spin Hall effect, which offers a powerful and flexible platform for controlling electromagnetic waves in information processing.

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All-in-one, all-optical logic gates using liquid metal plasmon nonlinearity

Cited by 6 publications

References 61 publications

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Ultra Low Power Consumption Optoelectronic Logic Operation of CuO/BaTiO₃ Heterojunction Photodetector with Tunable Internal Electric Field Based on Poling Effect

Photonic Spin‐Hall Logic Devices Based on Programmable Spoof Plasmonic Metamaterial

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All-in-one, all-optical logic gates using liquid metal plasmon nonlinearity

Cited by 6 publications

References 61 publications

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Surface Plasmon Waveguide Based on Nested Dielectric Parallel Nanowire Pairs Coated with Graphene

Ultra Low Power Consumption Optoelectronic Logic Operation of CuO/BaTiO3 Heterojunction Photodetector with Tunable Internal Electric Field Based on Poling Effect

Photonic Spin‐Hall Logic Devices Based on Programmable Spoof Plasmonic Metamaterial

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Product

Resources

About

Ultra Low Power Consumption Optoelectronic Logic Operation of CuO/BaTiO₃ Heterojunction Photodetector with Tunable Internal Electric Field Based on Poling Effect