Lattice ${\mathbb C} P^{N-1}$ model with ${\mathbb Z}_{N}$ twisted boundary condition: bions, adiabatic continuity and pseudo-entropy
Abstract: We investigate the lattice ${\mathbb C} P{N-1}$ sigma model on $S_{s}{1}$(large) $\times$ $S_{\tau}{1}$(small) with the ${\mathbb Z}{N}$ symmetric twisted boundary condition, where a sufficiently large ratio of the circumferences ($L{s}\gg L_{\tau}$) is taken to approximate ${\mathbb R} \times S1$. We find that the expectation value of the Polyakov loop, which is an order parameter of the ${\mathbb Z}N$ symmetry, remains consistent with zero ($|\langle P\rangle|\sim 0$) from small to relatively large inverse coupling $\beta$ (from large to small $L{\tau}$). As $\beta$ increases, the distribution of the Polyakov loop on the complex plane, which concentrates around the origin for small $\beta$, isotropically spreads and forms a regular $N$-sided-polygon shape (e.g. pentagon for $N=5$), leading to $|\langle P\rangle| \sim 0$. By investigating the dependence of the Polyakov loop on $S_{s}{1}$ direction, we also verify the existence of fractional instantons and bions, which cause tunneling transition between the classical $N$ vacua and stabilize the ${\mathbb Z}{N}$ symmetry. Even for quite high $\beta$, we find that a regular-polygon shape of the Polyakov-loop distribution, even if it is broken, tends to be restored and $|\langle P\rangle|$ gets smaller as the number of samples increases. To discuss the adiabatic continuity of the vacuum structure from another viewpoint, we calculate the $\beta$ dependence of ``pseudo-entropy" density $\propto\langle T{xx}-T_{\tau\tau}\rangle$. The result is consistent with the absence of a phase transition between large and small $\beta$ regions.
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