Abstract
We investigate the lattice ℂPN−1 sigma model on {S}_s^1 (large) × {S}_{tau}^1 (small) with the ℤN symmetric twisted boundary condition, where a sufficiently large ratio of the circumferences (Ls ≫ Lτ) is taken to approximate ℝ × S1. We find that the expectation value of the Polyakov loop, which is an order parameter of the ℤN symmetry, remains consistent with zero (|〈P〉| ∼ 0) from small to relatively large inverse coupling β (from large to small Lτ). As β increases, the distribution of the Polyakov loop on the complex plane, which concentrates around the origin for small β, isotropically spreads and forms a regular N-sided-polygon shape (e.g. pentagon for N = 5), leading to |〈P〉| ∼ 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 ℤN symmetry. Even for quite high β, we find that a regular-polygon shape of the Polyakov-loop distribution, even if it is broken, tends to be restored and |〈P〉| gets smaller as the number of samples increases. To discuss the adiabatic continuity of the vacuum structure from another viewpoint, we calculate the β dependence of “pseudo-entropy” density ∝ 〈Txx − Tττ〉. The result is consistent with the absence of a phase transition between large and small β regions.
Highlights
Taken to approximate the model on R × S1 with a periodic boundary condition (PBC)
It is of great importance to study the CP N−1 model on R × S1 with the ZN symmetric twisted boundary condition, with particular attentions to the ZN symmetry and its order parameter, namely the expectation value of the Polyakov loop P
Even in such high β regions, we find that a regular N -sided-polygon shape of the Polyakov-loop distribution tends to be restored and | P | gets smaller by increasing the number of samples
Summary
Let ω(x) be an N -component vector of complex scalar fields, a√nd φ(x) be a normalized complex N -component vector composed of ω as φ(x) ≡ ω(x)/ ω†ω. The action of the CP N−1 model in Euclidean two dimensions is given by. We consider (or approximate) the model on R × S1, and regard x and τ as coordinates of uncompactified (large) and compactified (small) directions, respectively. This model has instanton solutions characterized by the topological charge representing π2(CP N−1) Z. The simplest case, or the CP 1 model, is equivalent to the O(3) nonlinear sigma model, it can be described by three real scalar fields m(x) = (m1(x), m2(x), m3(x)) with a constraint m(x)2 = 1.
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