Nonparaxial Accelerating Electron Beams

Yongfeng Kang; Yiqi Zhang; Changbiao Li; Hua Zhong; Yanpeng Zhang; Milivoj R. Belic

doi:10.1109/JQE.2017.2677382

Nonparaxial Accelerating Electron Beams

Yongfeng Kang, Yiqi Zhang^*, Changbiao Li, Hua Zhong, Yanpeng Zhang, Milivoj R. Belic

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

We investigate nonparaxial accelerating electron beams theoretically in two and three dimensions. Starting from the Klein-Gordon equation, we obtain the Helmholtz equation for electron beams. We demonstrate that the electron beams can accelerate along semi-circular, parabolic, and semi-elliptic trajectories. The shape of the trajectory is determined by the input beam, which can be constructed by using phase masks that reflect the shape of the relevant special functions: half-Bessel, Weber, or half-Mathieu. The corresponding self-healing and ballistic-like effects of the nonparaxial accelerating beams are also demonstrated. The depth of the focus of the electron beam can be adjusted by the order of the function that is included in the input. Our investigation enriches the accelerating electron beam family, and provides new choices for improving the resolution of transmission electron microscope images.

Original language	English
Article number	7876743
Journal	IEEE Journal of Quantum Electronics
Volume	53
Issue number	2
DOIs	https://doi.org/10.1109/JQE.2017.2677382
Publication status	Published - Apr 2017
Externally published	Yes

Keywords

Bessel beams
Electron accelerating beams
Klein-Gordon equation
Mathieu beams
Weber beams

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10.1109/JQE.2017.2677382

Cite this

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title = "Nonparaxial Accelerating Electron Beams",

abstract = "We investigate nonparaxial accelerating electron beams theoretically in two and three dimensions. Starting from the Klein-Gordon equation, we obtain the Helmholtz equation for electron beams. We demonstrate that the electron beams can accelerate along semi-circular, parabolic, and semi-elliptic trajectories. The shape of the trajectory is determined by the input beam, which can be constructed by using phase masks that reflect the shape of the relevant special functions: half-Bessel, Weber, or half-Mathieu. The corresponding self-healing and ballistic-like effects of the nonparaxial accelerating beams are also demonstrated. The depth of the focus of the electron beam can be adjusted by the order of the function that is included in the input. Our investigation enriches the accelerating electron beam family, and provides new choices for improving the resolution of transmission electron microscope images.",

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AU - Kang, Yongfeng

AU - Zhang, Yiqi

AU - Li, Changbiao

AU - Zhong, Hua

AU - Zhang, Yanpeng

AU - Belic, Milivoj R.

PY - 2017/4

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AB - We investigate nonparaxial accelerating electron beams theoretically in two and three dimensions. Starting from the Klein-Gordon equation, we obtain the Helmholtz equation for electron beams. We demonstrate that the electron beams can accelerate along semi-circular, parabolic, and semi-elliptic trajectories. The shape of the trajectory is determined by the input beam, which can be constructed by using phase masks that reflect the shape of the relevant special functions: half-Bessel, Weber, or half-Mathieu. The corresponding self-healing and ballistic-like effects of the nonparaxial accelerating beams are also demonstrated. The depth of the focus of the electron beam can be adjusted by the order of the function that is included in the input. Our investigation enriches the accelerating electron beam family, and provides new choices for improving the resolution of transmission electron microscope images.

KW - Bessel beams

KW - Electron accelerating beams

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KW - Mathieu beams

KW - Weber beams

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Nonparaxial Accelerating Electron Beams

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