Abstract
High energy positrons can be efficiently created through high-energy photons splitting into electron-positron pairs under the influence of the Coulomb field. Here we show that a new degree of freedom-the intrinsic orbital angular momentum (OAM) can be introduced into relativistic positrons when the incident photons are twisted. We developed the full-twisted scattering theory to describe the transfer of angular momentum before and after the interaction. It is found that the total angular momentum (TAM) of the photon is equally distributed among the positron and electron. For each photon TAM value, the generated leptons gain higher average OAM number when the photon spin is anti-parallel to its TAM. The impact of photon polarization on the OAM spectrum profile and the scattering probability is more significant at small photon TAM numbers, owing to the various interaction channels influenced by flipping the photon spin. Our work provides the theoretical basis to study OAM physics in particle scattering and to obtain copious relativistic vortex positrons through the Beth-Heitler process.
Highlights
High-energy positrons are of great significance in modern particle physics experiments
It is found that the total angular momentum (TAM) of the photon is distributed between the positron and electron
The impact of photon polarization on the orbital angular momentum (OAM) spectrum profile and the scattering probability is more significant at small photon TAM numbers, owing to the various interaction channels influenced by flipping the photon spin
Summary
High-energy positrons are of great significance in modern particle physics experiments. Their collision with energetic electrons is essential in generating new particles such as B mesons/Z bosons [1,2] and monitoring various reaction processes via Bhabha scattering [3,4,5]. Interactions mainly concern the energy/momentum and the spin properties of the involved positrons. It was pointed out that particles can carry intrinsic orbital angular momentum (OAM) as they do for optical photons [10,11,12], in the presence of vortex states [13,14,15,16,17,18]. Interactions based on relativistic vortex particles have been studied in the framework of quantum
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