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Main Authors: Niu, Sen, Sheng, D. N., Peng, Yang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.21503
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author Niu, Sen
Sheng, D. N.
Peng, Yang
author_facet Niu, Sen
Sheng, D. N.
Peng, Yang
contents The emergence of chiral superconductivity from strongly correlated Mott regimes in purely repulsive, genuinely two-dimensional fermionic systems poses a key challenge, particularly when topology and superconducting long-range order must be treated on equal footing. Here we provide direct thermodynamic-limit evidence for chiral superconductivity in the triangular Hofstadter-Hubbard model relevant to moiré materials. This is achieved by advancing a simplex tensor-network formulation that simultaneously captures superconducting long-range order and chiral topological order in interacting fermionic systems with intrinsic charge fluctuations. We show that a chiral spin liquid occupies a broad intermediate-$U$ regime, forming a robust undoped parent state. Upon hole doping, we identify a uniform chiral superconducting phase in the infinite system, diagnosed directly by a finite complex pairing order parameter and chiral entanglement spectrum. The superconducting phase exhibits an almost universal phase winding across a wide interaction-doping region, together with a distinct pocket of opposite winding near the Mott criticality. These results establish thermodynamic-limit chiral superconductivity emerging from doped chiral topological states, revealing richer winding competition near the Mott transition point of the undoped system while preserving a common chiral topological character throughout the superconducting region.
format Preprint
id arxiv_https___arxiv_org_abs_2512_21503
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Thermodynamic-Limit Evidence for Chiral Superconductivity Induced by Doping Chiral Topological Phases
Niu, Sen
Sheng, D. N.
Peng, Yang
Strongly Correlated Electrons
The emergence of chiral superconductivity from strongly correlated Mott regimes in purely repulsive, genuinely two-dimensional fermionic systems poses a key challenge, particularly when topology and superconducting long-range order must be treated on equal footing. Here we provide direct thermodynamic-limit evidence for chiral superconductivity in the triangular Hofstadter-Hubbard model relevant to moiré materials. This is achieved by advancing a simplex tensor-network formulation that simultaneously captures superconducting long-range order and chiral topological order in interacting fermionic systems with intrinsic charge fluctuations. We show that a chiral spin liquid occupies a broad intermediate-$U$ regime, forming a robust undoped parent state. Upon hole doping, we identify a uniform chiral superconducting phase in the infinite system, diagnosed directly by a finite complex pairing order parameter and chiral entanglement spectrum. The superconducting phase exhibits an almost universal phase winding across a wide interaction-doping region, together with a distinct pocket of opposite winding near the Mott criticality. These results establish thermodynamic-limit chiral superconductivity emerging from doped chiral topological states, revealing richer winding competition near the Mott transition point of the undoped system while preserving a common chiral topological character throughout the superconducting region.
title Thermodynamic-Limit Evidence for Chiral Superconductivity Induced by Doping Chiral Topological Phases
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2512.21503