Entanglement entropy production in deep inelastic scattering
Kun Zhang, Kun Hao, Dmitri E. Kharzeev, V. E. Korepin
Abstract
Deep inelastic scattering (DIS) samples a part of the wave function of a hadron in the vicinity of the light cone. Lipatov constructed a spin chain which describes the amplitude of DIS in leading logarithmic approximation. Kharzeev and Levin proposed the entanglement entropy as an observable in DIS [Phys. Rev. D 95, 114008 (2017)], and suggested a relation between the entanglement entropy and parton distributions. Here we represent the DIS process as a local quench in Lipatov's spin chain and study the time evolution of the produced entanglement entropy. We show that the resulting entanglement entropy depends on time logarithmically, $\mathcal{S}(t)=1/3\mathrm{ln}(t/\ensuremath{\tau})$ with $\ensuremath{\tau}=1/m$ for $1/m\ensuremath{\le}t\ensuremath{\le}(mx{)}^{\ensuremath{-}1}$, where $m$ is the proton mass and $x$ is the Bjorken $x$. The central charge $c$ of Lipatov's spin chain is determined here to be $c=1$; using the proposed relation between the entanglement entropy and parton distributions, this corresponds to the gluon structure function growing at small $x$ as $xG(x)\ensuremath{\sim}1/{x}^{1/3}$.