Exact solution of the frustrated Potts model with next-nearest-neighbor interactions in one dimension via AI bootstrapping
Abstract
The one-dimensional (1D) J1-J2 q-state Potts model is solved exactly for arbitrary q by analytically block-diagonalizing the original q2× q2 transfer matrix into a simple 2× 2 maximally symmetric subspace, based on using OpenAI's reasoning model o3-mini-high to exactly solve the q=3 case. Furthermore, by matching relevant subspaces, we map the Potts model onto a simpler effective 1D q-state Potts model, where J2 acts as the nearest-neighbor interaction and J1 as an effective magnetic field, nontrivially generalizing a 56-year-old theorem previously limited to the simplest case (q=2, the Ising model). Our exact results provide insights to phenomena such as atomic or electronic order stacking in layered materials and the emergence of dome-shaped phases in complex phase diagrams. This work is anticipated to fuel both research in 1D frustrated magnets for recently discovered finite-temperature application potentials and the fast moving topic area of AI in science.
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