\begin{document}$Z = 119$\end{document}, we examined various combinations of projectiles and target nuclei used by different countries: Japan with \begin{document}$^{51}\text{V} + {}^{248}\text{Cm}$\end{document}, Russia potentially with \begin{document}$^{50}\text{Ti} + {}^{249}\text{Bk}$\end{document}, and China currently with \begin{document}$^{54}\text{Cr} + {}^{243}\text{Am}$\end{document}. Systematic investigations were conducted by varying the incident energy from 210 MeV to 260 MeV. We analyzed the capture cross sections, fusion probabilities, survival probabilities, and evaporation residue cross sections (ERCS) for each reaction to identify the optimal incident energy for synthesizing \begin{document}$Z = 119$\end{document}. Detailed plots were generated for these parameters as functions of the incident energy, thereby providing valuable insights for selecting the most effective incident energy for synthesizing \begin{document}$Z = 119$\end{document}."> Theoretical study of optimal synthesis conditions for superheavy element <i>Z</i> = 119 -
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