Hot Quarks and Gluons at an Electron-Ion Collider

TL;DR

This paper discusses the potential of an electron-ion collider to study gluon saturation effects in nuclei, which are crucial for understanding the behavior of nuclear matter at high energies and densities.

Contribution

It highlights the importance of an e+A collider in exploring gluon saturation and compares its potential to existing A+A collision results for understanding nuclear matter.

Findings

Gluon distribution grows rapidly at low x, risking unitarity violation.

Large nuclei amplify saturation effects at lower energies.

Proposals for e+A colliders aim to explore these phenomena in detail.

Abstract

The nuclear wave-function is dominated at low- and medium-x by gluons. As the rapid growth of the gluon distribution towards low x, as derived from current theoretical estimates, would violate unitarity, there must be a mechanism that tames this explosive growth. This is most efficiently studied in colliders running in e+A mode, as the nucleus is an efficient amplifier of saturation effects occurring with high gluon densities. In fact, large A can lead to these effects manifesting themselves at energies a few orders of magnitude lower than in e+p collisions. In order to study these effects, there are proposals to build an e+A machine in the USA, operating over a large range of masses and energies. These studies will allow for an in-depth comparison to A+A collisions where results have given tantalising hints of a new state of matter with partonic degrees of freedom. In order to explain these results quantitively, the gluons and their interactions must be understood fully as they are the dominant source of hard probes at both RHIC and LHC energies.