Wehrl entropy from coarse-graining the proton phase-space distribution supplies the appropriate initial entropy for hydrodynamics in small systems.
Quantum information approach to high energy interactions,
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Quantum systems reach a Maximal Entanglement Limit where entanglement geometry produces thermal reduced density matrices and probabilistic behavior in statistical and high-energy physics.
In unquenched scalar Yukawa theory, parton entanglement entropy encodes quantum information that cannot be reduced to Shannon entropy of parton distributions.
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Hydrodynamic Initial Conditions in Small Systems from Proton Phase-Space Entropy
Wehrl entropy from coarse-graining the proton phase-space distribution supplies the appropriate initial entropy for hydrodynamics in small systems.
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The Maximal Entanglement Limit in Statistical and High Energy Physics
Quantum systems reach a Maximal Entanglement Limit where entanglement geometry produces thermal reduced density matrices and probabilistic behavior in statistical and high-energy physics.
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Quantum entanglement between partons in a strongly coupled quantum field theory
In unquenched scalar Yukawa theory, parton entanglement entropy encodes quantum information that cannot be reduced to Shannon entropy of parton distributions.