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Bibliographic Details
Main Author: Levin, Eugene
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.02504
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author Levin, Eugene
author_facet Levin, Eugene
contents In this paper we found the multiplicity distribution of the produced dipoles in the final state for dipole-dipole scattering in the zero dimension toy models. This distribution shows the great differences from the distributions of partons in the wave function of the projectile. However, in spite of this difference the entropy of the produced dipoles turns out to be the same as the entropy of the dipoles in the wave function. This fact is not surprising since in the parton approach only dipoles in the hadron wave function which can be produced at $t = +\infty$ and measured by the detectors. We can also confirm the result of Kharzeev and Levin that this entropy is equal to $S_E = \ln\bigl(xG(x)\bigr)$, where we denote by $xG$ the mean multiplicity of the dipoles in the deep inelastic scattering. The evolution equations for $σ_n$ are derived.
format Preprint
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institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Particle production in the toy world: multiplicity distribution and entropy
Levin, Eugene
High Energy Physics - Phenomenology
In this paper we found the multiplicity distribution of the produced dipoles in the final state for dipole-dipole scattering in the zero dimension toy models. This distribution shows the great differences from the distributions of partons in the wave function of the projectile. However, in spite of this difference the entropy of the produced dipoles turns out to be the same as the entropy of the dipoles in the wave function. This fact is not surprising since in the parton approach only dipoles in the hadron wave function which can be produced at $t = +\infty$ and measured by the detectors. We can also confirm the result of Kharzeev and Levin that this entropy is equal to $S_E = \ln\bigl(xG(x)\bigr)$, where we denote by $xG$ the mean multiplicity of the dipoles in the deep inelastic scattering. The evolution equations for $σ_n$ are derived.
title Particle production in the toy world: multiplicity distribution and entropy
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2412.02504