A -valley Moir\'e Platform for Tunable Square Lattice Hubbard Model

Abstract

Moir\'e superlattices have emerged as a premier platform for simulating the Hubbard model, yet achieving high tunability in square-lattice systems remains a key challenge. We demonstrate that -valley twisted square homobilayers provide a faithful and highly tunable realization of t-t'-U Hubbard model, extending the recent proposal in M-valley systems. We show that at small twist angles, an emergent layer-exchange symmetry decouples electronic states into flat bands residing on two nested square sublattices. An interlayer displacement field breaks this symmetry to induce controllable inter-sublattice hybridization, enabling wide-range experimental tuning of the effective hopping ratio t'/t. By establishing a direct correspondence between - and M-valley systems, we provide a unified framework for understanding displacement-field tunability in square moir\'e physics. These findings establish -valley twisted bilayers as a versatile platform for simulating the square-lattice Hubbard model and exploring its rich landscape of correlated phenomena.

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