\begin{document}$a^{}_\mu \equiv (g^{}_\mu - 2)/2$\end{document} show a \begin{document}$4.2\sigma$\end{document} discrepancy between the theoretical prediction of the Standard Model and the experimental observations. To account for such a discrepancy, we consider a possible extension of the type-(I+II) seesaw model for neutrino mass generation with a gauged \begin{document}$L^{}_\mu - L^{}_\tau$\end{document} symmetry. By explicitly constructing an economical model with only one extra scalar singlet, we demonstrate that the gauge symmetry \begin{document}${U}(1)^{}_{L^{}_\mu - L^{}_\tau}$\end{document} and its spontaneous breaking are crucial not only for explaining the muon \begin{document}$(g - 2)$\end{document} result but also for generating the neutrino masses and leptonic flavor mixing. Various phenomenological implications and experimental constraints on the model parameters are also discussed."> Neutrino masses, leptonic flavor mixing, and muon (<i>g</i>−2) in the seesaw model with the <inline-formula><tex-math id="Z-20211215104619">\begin{document}$ {\boldsymbol U(1)^{}_{\boldsymbol L^{}_\mu - \boldsymbol L^{}_\tau} } $\end{document}</tex-math><alternatives><graphic xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="//www.macurncorp.com/hepnp/article/app/id/f076e52a-b149-4dcf-afa7-95012a4b1657/CPC-2021-0415_Z-20211215104619.jpg"/><graphic xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="//www.macurncorp.com/hepnp/article/app/id/f076e52a-b149-4dcf-afa7-95012a4b1657/CPC-2021-0415_Z-20211215104619.png"/></alternatives></inline-formula> gauge symmetry -
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