7 pages + appendix, 2 figures. References are added<br/>Spontaneous time-reversal symmetry breaking plays an important role in studying strongly correlated unconventional superconductors. When two superconducting gap functions with different symmetries compete, the relative phase channel ($θ_-\equiv θ_1-θ_2$) exhibits an Ising-type $Z_2$ symmetry due to the second order Josephson coupling, where $θ_{1,2}$ are the phases of two gap functions respectively. In contrast, the $U(1)$ symmetry in the channel of $θ_+\equiv \frac{θ_1+θ_2}{2}$ is intact. The phase locking, i.e., ordering of $θ_-$, can take place in the phase fluctuation regime before the onset of superconductivity, i.e. when $θ_+$ is disordered. If $θ_-$ is pinned at $\pm\fracπ{2}$, then time-reversal symmetry is broken in the normal state, otherwise, if $θ_-=0$, or, $π$, rotational symmetry is broken, leading to a nematic normal state. In both cases, the order parameters possess a 4-fermion structure beyond the scope of mean-field theory, which can be viewed as a high order symmetry breaking. We employ an effective two-component $XY$-model assisted by a renormalization group analysis to address this problem. As a natural by-product, we also find the other interesting intermediate phase corresponds to ordering of $θ_+$ but with $θ_-$ disordered. This is the quartetting, or, charge-4e, superconductivity, which occurs above the low temperature $Z_2$-breaking charge-2e superconducting phase. Our results provide useful guidance for studying novel symmetry breaking phases in strongly correlated superconductors.<br/>

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