A Novel Study of Neutron Structure Function $F_2^{\rm n}$ from Maximum Entropy Method

We apply the Maximum Entropy Method to determine valence quark distributions of the neutron at a low scale $Q_0^2$. At the initial evolution scale $Q_0^2$, there are no sea quark and gluon distributions except for that of the three valence quarks (udd). Using the DGLAP equations with parton-parton recombination corrections (nonlinear effect), we obtain the neutron structure function $F_2^{\rm n}$ at any high scale $Q^2$. The predicted structure function ratio $F_2^{\rm n}$/$F_{2}^{\rm p}$ is approximatively consistent with the world DIS data of proton and deuteron targets, if the uncertainties caused by model-dependent corrections are taken into account. Furthermore, our obtained $F_2^{\rm n}/F_{2}^{\rm p}$ ratio basically agrees with BONuS experimental results after considering both the contamination from the nucleon resonances around $x\gtrsim 0.4, 0.5, 0.6$ and the contribution of systematic uncertainties. The predicted $F_2^{\rm n}/F_{2}^{\rm p}$ and $u/d$ ratios under the limit of $x\rightarrow 1$ are compared with the theoretical calculations. Finally, we check that the parton distributions of proton and neutron approximately satisfy isospin symmetry in this work.
Comment: 6 pages, 8 figures