Emergent Nonthermal Fluid from Jets in the Massive Schwinger Model Using Tensor Networks

Romuald A. Janik; Maciej A. Nowak; Marek M. Rams; Ismail Zahed

doi:10.1103/gvr2-gqys

Emergent Nonthermal Fluid from Jets in the Massive Schwinger Model Using Tensor Networks

Romuald A. Janik
, Maciej A. Nowak
, Marek M. Rams
, Ismail Zahed

Physics and Astronomy

Jagiellonian University in Kraków

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

We analyze the correlation between the energy, momentum, and spatial entanglement produced by two luminal jets in the massive Schwinger model. Using tensor network methods, we show that for m/g>1/π, in the vicinity of the strong- to weak-coupling transition, a nearly perfect and chargeless effective fluid behavior appears around the midrapidity region with a universal energy-pressure relationship. The evolution of energy and pressure is strongly correlated with the rise of the spatial entanglement entropy, indicating a key role of quantum dynamics. Some of these observations may be used to analyze high multiplicity jet fragmentation events, energy-energy and energy-charge correlators at current collider energies.

Original language	English
Article number	211903
Journal	Physical Review Letters
Volume	135
Issue number	21
DOIs	https://doi.org/10.1103/gvr2-gqys
State	Published - Nov 21 2025

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title = "Emergent Nonthermal Fluid from Jets in the Massive Schwinger Model Using Tensor Networks",

abstract = "We analyze the correlation between the energy, momentum, and spatial entanglement produced by two luminal jets in the massive Schwinger model. Using tensor network methods, we show that for m/g>1/π, in the vicinity of the strong- to weak-coupling transition, a nearly perfect and chargeless effective fluid behavior appears around the midrapidity region with a universal energy-pressure relationship. The evolution of energy and pressure is strongly correlated with the rise of the spatial entanglement entropy, indicating a key role of quantum dynamics. Some of these observations may be used to analyze high multiplicity jet fragmentation events, energy-energy and energy-charge correlators at current collider energies.",

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AU - Rams, Marek M.

AU - Zahed, Ismail

N1 - Publisher Copyright: © 2025 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the "https://creativecommons.org/licenses/by/4.0/"Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI. Funded by SCOAP3.

PY - 2025/11/21

Y1 - 2025/11/21

N2 - We analyze the correlation between the energy, momentum, and spatial entanglement produced by two luminal jets in the massive Schwinger model. Using tensor network methods, we show that for m/g>1/π, in the vicinity of the strong- to weak-coupling transition, a nearly perfect and chargeless effective fluid behavior appears around the midrapidity region with a universal energy-pressure relationship. The evolution of energy and pressure is strongly correlated with the rise of the spatial entanglement entropy, indicating a key role of quantum dynamics. Some of these observations may be used to analyze high multiplicity jet fragmentation events, energy-energy and energy-charge correlators at current collider energies.

AB - We analyze the correlation between the energy, momentum, and spatial entanglement produced by two luminal jets in the massive Schwinger model. Using tensor network methods, we show that for m/g>1/π, in the vicinity of the strong- to weak-coupling transition, a nearly perfect and chargeless effective fluid behavior appears around the midrapidity region with a universal energy-pressure relationship. The evolution of energy and pressure is strongly correlated with the rise of the spatial entanglement entropy, indicating a key role of quantum dynamics. Some of these observations may be used to analyze high multiplicity jet fragmentation events, energy-energy and energy-charge correlators at current collider energies.

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ER -

Emergent Nonthermal Fluid from Jets in the Massive Schwinger Model Using Tensor Networks

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