A comprehensive guide to the physics and usage of PYTHIA 8.3 (2203.11601v1)

Abstract: This manual describes the PYTHIA 8.3 event generator, the most recent version of an evolving physics tool used to answer fundamental questions in particle physics. The program is most often used to generate high-energy-physics collision "events", i.e. sets of particles produced in association with the collision of two incoming high-energy particles, but has several uses beyond that. The guiding philosophy is to produce and reproduce properties of experimentally obtained collisions as accurately as possible. The program includes a wide ranges of reactions within and beyond the Standard Model, and extending to heavy ion physics. Emphasis is put on phenomena where strong interactions play a major role. The manual contains both pedagogical and practical components. All included physics models are described in enough detail to allow the user to obtain a cursory overview of used assumptions and approximations, enabling an informed evaluation of the program output. A number of the most central algorithms are described in enough detail that the main results of the program can be reproduced independently, allowing further development of existing models or the addition of new ones. Finally, a chapter dedicated fully to the user is included towards the end, providing pedagogical examples of standard use cases, and a detailed description of a number of external interfaces. The program code, the online manual, and the latest version of this print manual can be found on the PYTHIA web page: https://www.pythia.org/

• The paper details the comprehensive simulation framework of PYTHIA 8.3, integrating hard collisions, diverse parton shower algorithms, and hadronization models.
• It explains various physics models including hard interactions, soft QCD processes, and multi-parton interactions to align simulations with experimental data.
• The guide highlights practical applications in high-energy research and offers strategies for tuning models and exploring new physics scenarios.

Overview of the Pythia Event Generator

The Pythia event generator is an extensive modular software framework employed for simulating particle physics events, especially in high-energy collisions. The generator is a comprehensive tool for modeling the evolution of particle interactions from initial high-energy collisions to final observable states. This document presents a detailed guide on its implementation and usage, covering a range of physics phenomena within the field of particle physics.

Purpose and Utility

Pythia is widely used to simulate high-energy particle collisions, typically occurring in accelerators like the LHC. Its chief utility lies in modeling collision events, where two incoming high-energy particles collide, resulting in a plethora of outgoing particles. The aim is to produce results that closely mimic experimental data. Consequently, Pythia incorporates both theoretical physics models and phenomenological adjustments to align simulation outcomes with empirical observations.

Physics Models and Algorithms

Pythia includes an extensive array of physics models:

• Hard Interactions: Involve high-energy interactions described by perturbative QCD and electroweak processes, allowing the simulation of hard scattering events that initiate particle showers.
• Parton Showers: Describe the evolution of initial states through successive emissions of quarks and gluons before hadronization. Pythia includes several algorithms for shower evolution, including the simple shower, Dire, and Vincia.
• Hadronization: Transition from partons to hadrons, typically modeled using the Lund string fragmentation model, but also incorporating models like cluster fragmentation for specific processes.
• Multi-parton Interactions and Underlying Event: Models interactions beyond the primary collision, contributing to the soft particle production also known as the underlying event.
• Special Physics Processes: Includes treatment of new physics scenarios, exploring the phenomenology of processes beyond the Standard Model, such as supersymmetry and hidden sectors.

Parton Shower Algorithms

The document delineates three main types of shower evolution processes:

• Simple Showers: Basic yet robust implementation focusing on a leading-logarithm approximation, with options for matrix element corrections and variations for systematic uncertainty studies.
• Vincia Antenna Showers: Employs an antenna approach offering coherent treatment of soft radiation, enabling fine-tuned control of colour coherence effects.
• Dire Showers: Combines aspects of dipole and parton showers, focusing on soft-collinear radiation ensuring a more accurate representation of such emissions.

Phase Space and Recoil Schemes

Effective event generation requires thorough phase-space sampling using sophisticated techniques for mapping final-state particle kinematics. Pythia adopts several recoil schemes in parton showers to maintain momentum conservation and proper branching histories in complex multiparticle interactions.

Soft and Non-Perturbative QCD

Pythia goes beyond hard scatterings to address the regulated modeling of soft QCD processes that are dominated by non-perturbative physics. These include phenomena like diffraction, photon-induced reactions, and heavy-ion collisions, which portray the complex landscape beneath the letterbox of hard-scattering theory.

Applications and Extensions

Beyond standard applications in simulating typical particle interactions, Pythia is adaptable to user-specific scenarios, permitting the integration of new models and tuning to particular experimental setups. The generator supports external inputs through interfaces such as the Les Houches Accord for events and PDF settings, broadening its utility across various experimental and theoretical studies.

Conclusion and Future Directions

The Pythia event generator represents a foundational tool in computational particle physics, facilitating a bridge between theoretical predictions and experimental findings. Continuous development of the tool aligns it closer with evolving experimental data, whilst also extending its applicability to new realms of physics. Future advancements are expected to enhance its precision and scope, particularly in the integration of higher-order corrections and novel physics scenarios. Pythia's robust framework and adaptability will undoubtedly continue to serve as an indispensable resource for physicists exploring the quantum world of particle interactions.