Twisted particle collisions: a new tool for spin physics
Abstract
Collisions of twisted particles --- that is, non-plane-wave states of photons, electrons, or any other particle, equipped with a non-zero orbital angular momentum (OAM) with respect to its propagation direction --- offer novel ways to probe particle structure and interactions. In the recent paper \cite{Ivanov:2019vxe}, we argued that resonance production in twisted photon collisions or twisted annihilation gives access to parity- and spin-sensitive observables in inclusive cross sections, even when the initial particles are unpolarized. Here, we explore these features in detail, providing a qualitative picture and illustrating it with numerical examples. We show how one can detect parity-violating effects in collisions of unpolarized twisted photons and how one can produce almost polarized vector mesons in unpolarized twisted annihilation. These examples highlight the unprecedented level of control over polarization offered by twisted particles, impossible in the usual plane wave collisions.
Cite
@article{arxiv.2002.01703,
title = {Twisted particle collisions: a new tool for spin physics},
author = {Igor P. Ivanov and Nikolai Korchagin and Alexandr Pimikov and Pengming Zhang},
journal= {arXiv preprint arXiv:2002.01703},
year = {2020}
}
Comments
26 pages, 9 figures