What question did this study set out to answer?

This research aims to develop a method for the effective generation, collimation, and acceleration of positrons using laser-electron interactions.

June 20, 2026Open Access

Positron collimation driven by channel fields excited by a Doppler-boosted laser pulse in the prefilled target

Key Points

This research aims to develop a method for the effective generation, collimation, and acceleration of positrons using laser-electron interactions.
Utilized an all-optical configuration involving a Doppler-boosted laser interacting with an electron beam in a channel target.
Assessed beam divergence angle and positron bunch density during the interaction.
Implemented techniques for spatial and spectral separation of positrons from background electrons.
Achieved a peak positron density of approximately 10^28 m−3 with a duration of about 27 fs.
Reduced the beam divergence angle from 40° to 23°.
Projected the monoenergetic peak energy upshifting to hundreds of MeV.

Abstract

We propose an all-optical configuration for the integrated generation, collimation, and acceleration of positrons with laser–electron beam interaction in a channel target. The electromagnetic fields driven by a Doppler-boosted laser within the channel yield a high-collimated dense positron bunch (with a peak density of ∼1028 m−3 and a duration of ∼27 fs). With the channel target, the beam divergence angle (FWHM) is decreased from 40° to 23°, and the monoenergetic peak is expected to upshift to hundreds of MeV. Moreover, automatic spatial and spectral separation between positrons and background electrons is also achieved, providing a promising scheme for future high-quality positron generation in compact integrated devices.

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