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Hauptverfasser: Kariyado, Toshikaze, Wicaksono, Yusuf, Vishwanath, Ashvin, Volkov, Pavel, Luo, Zhu-Xi
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2603.11153
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author Kariyado, Toshikaze
Wicaksono, Yusuf
Vishwanath, Ashvin
Volkov, Pavel
Luo, Zhu-Xi
author_facet Kariyado, Toshikaze
Wicaksono, Yusuf
Vishwanath, Ashvin
Volkov, Pavel
Luo, Zhu-Xi
contents Novel superconducting phases have been found in various moiré heterostructures based on hexagonal lattices. However, the archetypal high-temperature superconductors (cuprates, iron-based and nickelate families) all share a square lattice foundation. These materials host a rich landscape of correlated phenomena, such as charge and spin stripes, pseudogap behavior, and unconventional metallicity, which continue to challenge our fundamental understanding of strongly correlated electrons. In this work, we investigate the possibility of simulating the effective models governing these high-$T_c$ superconductors using twisted homobilayers of $Γ$-valley square-lattice systems. We develop a universal theoretical framework and carry out a detailed analysis of a promising candidate material ZnF$_2$. We find that the first moiré band realizes a single-orbital square-lattice Hubbard model, widely believed to capture cuprate physics, while the second and third moiré bands map to a $p_x,p_y$ two-orbital square-lattice Hubbard model, which shares common physics to the minimal $d_{xz}, d_{yz}$ models proposed for iron pnictides. Our study combines continuum Hamiltonian modeling, first-principle calculations, and Hartree-Fock mean field theory. The latter focuses on the quarter-filling regime of the two-orbital model and in particular leads to, among others, a stable antiferro-orbital, ferromagnetic insulating phase. These results highlight $Γ$-valley square-lattice moiré systems as a new and important generation of van der Waals heterostructures to realize interesting strongly correlated phases of matter.
format Preprint
id arxiv_https___arxiv_org_abs_2603_11153
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Moiré in $Γ$-valley square lattice: Copper- and iron-based superconductor simulation in a single device
Kariyado, Toshikaze
Wicaksono, Yusuf
Vishwanath, Ashvin
Volkov, Pavel
Luo, Zhu-Xi
Strongly Correlated Electrons
Materials Science
Superconductivity
Novel superconducting phases have been found in various moiré heterostructures based on hexagonal lattices. However, the archetypal high-temperature superconductors (cuprates, iron-based and nickelate families) all share a square lattice foundation. These materials host a rich landscape of correlated phenomena, such as charge and spin stripes, pseudogap behavior, and unconventional metallicity, which continue to challenge our fundamental understanding of strongly correlated electrons. In this work, we investigate the possibility of simulating the effective models governing these high-$T_c$ superconductors using twisted homobilayers of $Γ$-valley square-lattice systems. We develop a universal theoretical framework and carry out a detailed analysis of a promising candidate material ZnF$_2$. We find that the first moiré band realizes a single-orbital square-lattice Hubbard model, widely believed to capture cuprate physics, while the second and third moiré bands map to a $p_x,p_y$ two-orbital square-lattice Hubbard model, which shares common physics to the minimal $d_{xz}, d_{yz}$ models proposed for iron pnictides. Our study combines continuum Hamiltonian modeling, first-principle calculations, and Hartree-Fock mean field theory. The latter focuses on the quarter-filling regime of the two-orbital model and in particular leads to, among others, a stable antiferro-orbital, ferromagnetic insulating phase. These results highlight $Γ$-valley square-lattice moiré systems as a new and important generation of van der Waals heterostructures to realize interesting strongly correlated phases of matter.
title Moiré in $Γ$-valley square lattice: Copper- and iron-based superconductor simulation in a single device
topic Strongly Correlated Electrons
Materials Science
Superconductivity
url https://arxiv.org/abs/2603.11153