Latest Research Papers

We present a novel quantum Monte Carlo scheme for evaluating the $\alpha$-stabilizer R\'enyi entropy (SRE) with any integer $\alpha\ge 2$. By interpreting $\alpha$-SRE as a ratio of generalized partition functions, we prove that it can be simulated by sampling reduced Pauli strings within a reduced configuration space. This allows for straightforward computation of the values and derivatives of $\alpha$-SRE using techniques such as reweight-annealing and thermodynamic integration. Moreover, our approach separates the free energy contribution in $\alpha$-SRE, thus the contribution solely from the characteristic function can be studied, which is directly tied to magic. In our applications to the ground states of 1D and 2D transverse field Ising (TFI) model, we reveal that the behavior of $2$-SRE is governed by the interplay between the characteristic function and the free energy contributions, with singularities hidden in both of their derivatives at quantum critical points. This indicates that $\alpha$-SRE does not necessarily exhibit a peak at the quantum critical point for a general many-body system. We also study the volume-law corrections to the ground-state magic. These corrections slightly violate the strict volume law and suggest discontinuity at quantum critical points, which we attribute to the abrupt change of the ground-state magical structure. Our findings suggest that volume-law corrections of magic are stronger diagnostics for criticalities than the full-state magic. Lastly, we study the finite-temperature phase transition of the 2D TFI model, where the $2$-SRE is not a well-defined magic measure. The nonphysical results we obtain also prove the ineffectiveness of $2$-SRE for mixed states. Our method enables scalable and efficient evaluation of $\alpha$-SRE in large-scale quantum systems, providing a powerful tool for exploring the roles of magic in many-body systems.