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    Optical‐Field‐Driven Electron Tunneling in Metal–Insulator–Metal Nanojunction

    New search for: Zhou, Shenghan
    New search for: Guo, Xiangdong
    New search for: Chen, Ke
    New search for: Cole, Matthew Thomas
    New search for: Wang, Xiaowei
    New search for: Li, Zhenjun
    New search for: Dai, Jiayu
    New search for: Li, Chi
    New search for: Dai, Qing

    Optical‐field driven electron tunneling in nanojunctions has made demonstrable progress toward the development of ultrafast charge transport devices at subfemtosecond time scales, and have evidenced great potential as a springboard technology for the next generation of on‐chip “lightwave electronics.” Here, the empirical findings on photocurrent the high nonlinearity in metal–insulator–metal (MIM) nanojunctions driven by ultrafast optical pulses in the strong optical‐field regime are reported. In the present MIM device, a 14th power‐law scaling is identified, never achieved before in any known solid‐state device. This work lays important technological foundations for the development of a new generation of ultracompact and ultrafast electronics devices that operate with suboptical‐cycle response times.

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    Optical‐Field‐Driven Electron Tunneling in Metal–Insulator–Metal Nanojunction

    New search for: Zhou, Shenghan
    New search for: Guo, Xiangdong
    New search for: Chen, Ke
    New search for: Cole, Matthew Thomas
    New search for: Wang, Xiaowei
    New search for: Li, Zhenjun
    New search for: Dai, Jiayu
    New search for: Li, Chi
    New search for: Dai, Qing

    Optical‐field driven electron tunneling in nanojunctions has made demonstrable progress toward the development of ultrafast charge transport devices at subfemtosecond time scales, and have evidenced great potential as a springboard technology for the next generation of on‐chip “lightwave electronics.” Here, the empirical findings on photocurrent the high nonlinearity in metal–insulator–metal (MIM) nanojunctions driven by ultrafast optical pulses in the strong optical‐field regime are reported. In the present MIM device, a 14th power‐law scaling is identified, never achieved before in any known solid‐state device. This work lays important technological foundations for the development of a new generation of ultracompact and ultrafast electronics devices that operate with suboptical‐cycle response times.

    Access

    Download

    Optical‐Field‐Driven Electron Tunneling in Metal–Insulator–Metal Nanojunction

    New search for: Zhou, Shenghan
    New search for: Guo, Xiangdong
    New search for: Chen, Ke
    New search for: Cole, Matthew Thomas
    New search for: Wang, Xiaowei
    New search for: Li, Zhenjun
    New search for: Dai, Jiayu
    New search for: Li, Chi
    New search for: Dai, Qing

    Optical‐field driven electron tunneling in nanojunctions has made demonstrable progress toward the development of ultrafast charge transport devices at subfemtosecond time scales, and have evidenced great potential as a springboard technology for the next generation of on‐chip “lightwave electronics.” Here, the empirical findings on photocurrent the high nonlinearity in metal–insulator–metal (MIM) nanojunctions driven by ultrafast optical pulses in the strong optical‐field regime are reported. In the present MIM device, a 14th power‐law scaling is identified, never achieved before in any known solid‐state device. This work lays important technological foundations for the development of a new generation of ultracompact and ultrafast electronics devices that operate with suboptical‐cycle response times.

    Access

    Download

    Access

    Download

    Page navigation

    Document information
    Similar titles

    Export, share and cite

    Document information
    Title:

    Optical‐Field‐Driven Electron Tunneling in Metal–Insulator–Metal Nanojunction

    Contributors:

    Zhou, Shenghan (author) / Guo, Xiangdong (author) / Chen, Ke (author) / Cole, Matthew Thomas (author) / Wang, Xiaowei (author) / Li, Zhenjun (author) / Dai, Jiayu (author) / Li, Chi (author) / Dai, Qing (author)

    Published in:

    Advanced Science ; 8

    Publication date:

    2021-12-01

    Size:

    7 pages

    ISSN:

    2198-3844

    DOI:

    https://doi.org/10.1002/advs.202101572

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    English

    Keywords:

    optical‐field‐driven tunneling , ultrafast electronics , high nonlinearity , MIM nanojunction

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