Introduction to the physics of the total cross-section at LHC: A Review of Data and Models

TL;DR

This comprehensive review traces the development of hadronic total cross-section physics at the LHC, integrating experimental data, cosmic ray insights, and theoretical models to understand high-energy particle interactions and QCD phenomena.

Contribution

It provides a historical and theoretical overview of total cross-section studies, highlighting recent LHC results and their implications for QCD and high-energy physics models.

Findings

Total cross-sections increase with energy, probing soft and hard QCD regimes.

Cosmic ray data extend the energy range, aiding asymptotic behavior studies.

Experimental results support and refine Regge and diffractive models.

Abstract

This review describes the development of the physics of hadronic cross sections up to recent LHC results and cosmic ray experiments. We present here a comprehensive review - written with a historical perspective - about total cross-sections from medium to the highest energies explored experimentally and studied through a variety of methods and theoretical models for over sixty years. We begin by recalling the analytic properties of the elastic amplitude and the theorems about the asymptotic behavior of the total cross-section. A discussion of how proton-proton cross-sections are extracted from cosmic rays at higher than accelerator energies and help the study of these asymptotic limits, is presented. This is followed by a description of the advent of particle colliders, through which high energies and unmatched experimental precisions have been attained. Thus the measured hadronic elastic and total cross-sections have become crucial instruments to probe the so called soft part of QCD physics, where quarks and gluons are confined, and have led to test and refine Regge behavior and a number of diffractive models. As the c.m. energy increases, the total cross-section also probes the transition into hard scattering describable with perturbative QCD, the so-called mini-jet region. Further tests are provided by cross-section measurements of gamma p, gamma*p and gamma* gamma* for models based on vector meson dominance, scaling limits of virtual photons at high Q^2 and the BFKL formalism. Models interpolating from virtual to real photons are also tested.