Angular Distribution of Dimuons from Drell-Yan Production in p+Fe Interactions at 120 GeV Beam Energy

In the E906/SeaQuest Fermilab experiment, we report a measurement of the angular distributions by measuring the angular parameters $$\lambda$$, $$\mu$$, and $$\nu$$ of Drell-Yan dimuons produced using a 120 GeV proton beam incident on an iron target. The angular distribution in the naive Drell-Yan model does not show any $$\cos2\phi$$ dependency, where $$\phi$$ denotes the azimuthal angle of dimuons in the Collins-Soper frame. However, pion-induced Drell-Yan experiments, such as NA10 and E615, have observed a significant dependence on $$\cos2\phi$$. The Boer–Mulders function, a transverse momentum-dependent distribution function, represents the correlation between the transverse spin and the transverse momentum of the quark. A non-zero Boer-Mulders function or an improved higher-order Drell-Yan model considering QCD effects can produce a $$\cos 2\phi$$ modulation in the Drell-Yan angular distribution. To measure the angular distributions, we have used an event mixing method to construct the combin atorial background, which was then subtracted from the data to isolate the Drell-Yan signal. Following this, we corrected the detector, trigger, and reconstruction efficiencies using a doubly-iterative Bayesian Unfolding method. This iterative unfolding technique improves the response matrix based on the results of the previous unfolding step, ensuring robust convergence without exaggeration of uncertainties. The angular distributions of the dimuons were measured over the invariant mass range $$5.0 < M_{\mu^+ \mu^-} < 8.0$$ $GeV/c^2$, with dimuon transverse momentum $$P_T < 2$$ GeV/c and Feynman-x $$-0.18 < x_F < 0.9$$. The measured angular distributions are then compared with the QCD calculations for $$p + \text{Fe}$$ interactions, and proton-induced angular distribution measurements from other experiments. We have observed weak $$\cos 2\phi$$ modulations as a function of $$P_T$$. For $$P_T > 1.0 \, \text{GeV}/c$$, the predicted NNLO perturbative QCD value of $$\nu$$ is larger than what we have me asured at E906/SeaQuest. Moreover, we have not observed a strong dependence of $$\nu$$ on the kinematic variables, such as dimuon mass $$M_{\mu^+ \mu^-}$$ and Bjorken-$$x$$. The spin alignment of the virtual photon, $$\lambda$$, measured from the SeaQuest Drell-Yan $$p+\text{Fe}$$ data, is found to be strongly dependent on $$P_T$$, decreasing as $$P_T$$ increases. $$\lambda$$ also holds to the upper bound condition $$\lambda < 1.0$$ within the statistical uncertainty, showing a trend similar to that predicted by NNLO perturbative QCD. However, for $$1.0 < P_T < 2.0 \, \text{GeV}/c$$, the extracted $$\lambda$$ value from SeaQuest is smaller than that predicted by perturbative QCD at NNLO.