Study of electron emission from 1D nanomaterials under super high field
Chi Li, Ke Chen, Mengxue Guan, Xiaowei Wang, Xu Zhou, Feng Zhai, Jiayu, Dai, Zhenjun Li, Zhipei Sun, Sheng Meng, Kaihui Liu, Qing Dai

TL;DR
This paper demonstrates a highly nonlinear strong-field photoemission from carbon nanotubes, enabling improved control of electron pulses and opening new avenues for attosecond technology and nanomaterial design.
Contribution
It introduces a new extreme nonlinear photoemission regime from nanomaterials, with a 40th power law dependence and tunable dynamics, advancing attosecond science.
Findings
Photoemission current scales with the 40th power of optical-field strength.
Total photoemission current depends on carrier-envelope phase with 100% modulation.
Tunable nonlinear dynamics linked to valence band binding energy.
Abstract
Photoemission driven by a strong electric field of near-infrared or visible light, referred to as strong-field photoemission, produces attosecond electron pulses that are synchronized to the waveform of the incident light, and this principle lies at the heart of current attosecond technologies. However, full access to strong-field photoemission regimes at near-infrared wavelengths based on solid-state materials is restricted by space-charge screening and material damage at high optical-field strengths, which significantly hampers the realization of predicted attosecond technologies, such as ultra-sensitive optical phase modulation. Here, we demonstrate a new type of strong-field photoemission behaviour with extreme nonlinearity -- photoemission current scales follow a 40th power law of the optical-field strength, making use of sub-nanometric carbon nanotubes and 800 nm pulses. As a…
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Taxonomy
TopicsLaser-Matter Interactions and Applications · Advanced Fiber Laser Technologies · Terahertz technology and applications
