The successes and limitations of statistical sampling for a sequence of models studied in the
context of lattice QCD are discussed and the need for new methods to deal with finite …

We study the effect of spatial anisotropy on polar flocks by investigating active q-state clock
models in two dimensions. In contrast to the equilibrium case, we find that any amount of …

We simulate the phase diagram and critical behavior of the q-state clock model on the
square lattice by using the state-of-the-art loop optimization for tensor-network …

Renormalization group theory of tensor network states provides a powerful tool for studying
quantum many-body problems and a new paradigm for understanding entangled structures …

We propose a general mechanism to realize nematic superconductivity (SC) and reveal its
exotic vestigial phases in the quasicrystal (QC). Starting from a Penrose-Hubbard model, our …

Quantum phase transitions between different topologically ordered phases exhibit rich
structures and are generically challenging to study in microscopic lattice models. In this …

By using extensive tensor network calculations, we map out the phase diagram of the
frustrated J 1-J 2 Ising model on the square lattice. In particular, we focus on the cases with …

It is known that the loss of phase coherence of Cooper pairs in two-dimensional
superconductivity corresponds to the unbinding of vortex-antivortex pairs with the quasi-long …

Fracton codes host unconventional topological states of matter and are promising for fault-
tolerant quantum computation due to their large coding space and strong resilience against …

In this paper, a modified method of anomaly detection using convolutional autoencoders is
employed to predict phase transitions in several statistical mechanical models on a square …