Half-ice, half-fire-driven ultranarrow phase crossover in one-dimensional decorated q-state Potts ferrimagnets: An AI-co-led exploration

Abstract

OpenAI's reasoning model o3-mini-high was used to carry out an exact analytic study of one-dimensional ferrimagnetic site- and bond-decorated q-state Potts models. We demonstrate that the finite-temperature ultranarrow phase crossover (UNPC), driven by a hidden "half-ice, half-fire" state recently discovered in the q=2 case (Ising model), persists for q>2. Moreover, we identify unique features for q>2, including the dome structure in the field-temperature phase diagram, and for large q a secondary high-temperature UNPC to the fully disordered paramagnetic state. As the UNPC quickly approaches a genuine transition by enhancing J, the interaction between the backbone spins, two distinct behaviors emerge: In the site-decorated Potts model, T0 is independent of J and thus remains unchanged (Type-I UNPC), and in the bond-decorated Potts model with q > 2, T0 depends on J and quickly shifts toward a finite temperature as J increases (Type-II UNPC). These results establish a versatile framework for engineering controlled fast state-flipping switches in low-dimensional systems. Our nine-dan artificial intelligence (AI)-contribution framework assigns AI the meritorious status of AI-co-led discovery in this work.