\begin{document}$ u $\end{document} and \begin{document}$ d $\end{document} quarks. Recently, it was suggested that the universality for heavy flavors can be studied through their deep subthreshold production in \begin{document}$ \gamma A $\end{document} and eA collisions. In this paper, we discuss an alternative possibility to access the strange and gluon high-X structure of the SRC and to establish universality for heavy flavors using nuclear semi-inclusive deep inelastic scattering (nSIDIS), which probes different quark flavor combinations depending on the final state hadron. The specific reaction can be "tagged" by observation of a strange or charmed particle registered in coincidence with the scattering lepton. The universality of the SRC can be tested in the kinematic region, i.e., \begin{document}$ X>1 $\end{document}, where the contribution to the cross section from SRC becomes dominant. Exploring the strangeness, charmonium, and open charm will shed light on the role of quarks and gluons in nuclei, thereby developing an understanding of how nuclei emerge within QCD."> Universality test of short range nucleon-nucleon correlations in nuclei with strange and charmed probes -
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