Litcius/Paper detail

Entanglement entropy of the proton in coordinate space

Adrian Dumitru, Alex Kovner, Vladimir V. Skokov

2023Physical review. D/Physical review. D.12 citationsDOIOpen Access PDF

Abstract

We calculate the entanglement entropy of a model proton wave function in coordinate space by integrating out degrees of freedom outside a small circular region $\overline{A}$ of radius $L$, where $L$ is much smaller than the size of the proton. The wave function provides a nonperturbative distribution of three valence quarks. In addition, we include the perturbative emission of a single gluon and calculate the entanglement entropy of gluons in $\overline{A}$. For both quarks and gluons, we obtain the same simple result: ${S}_{E}=\ensuremath{-}\ensuremath{\int}\frac{dx}{\mathrm{\ensuremath{\Delta}}x}{N}_{{L}^{2}}(x)\mathrm{log}[{N}_{{a}^{2}}(x)]$, where $a$ is the UV cutoff in coordinate space and $\mathrm{\ensuremath{\Delta}}x$ is the longitudinal resolution scale. Here ${N}_{S}(x)$ is the number of partons (of the appropriate species) with longitudinal momentum fraction $x$ inside an area $S$. It is related to the standard parton distribution function by ${N}_{S}(x)=\frac{S}{{A}_{p}}\mathrm{\ensuremath{\Delta}}xF(x)$, where ${A}_{p}$ denotes the transverse area of the proton.

Topics & Concepts

PhysicsPartonGluonCoordinate spaceParticle physicsQuarkPosition and momentum spaceQuantum entanglementProtonDistribution functionWave functionMathematical physicsQuantum mechanicsGeometryQuantumMathematicsHigh-Energy Particle Collisions ResearchBlack Holes and Theoretical PhysicsParticle physics theoretical and experimental studies