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Autores principales: Wang, Yi-Jie, Zhou, Geng-Dong, Jung, Hyunsung, Youn, Seongyeon, Lee, Seung-Sup B., Song, Zhi-Da
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2510.23604
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author Wang, Yi-Jie
Zhou, Geng-Dong
Jung, Hyunsung
Youn, Seongyeon
Lee, Seung-Sup B.
Song, Zhi-Da
author_facet Wang, Yi-Jie
Zhou, Geng-Dong
Jung, Hyunsung
Youn, Seongyeon
Lee, Seung-Sup B.
Song, Zhi-Da
contents Recent experiments support that the magic-angle graphene can be modeled by a periodic array of correlated quantum impurities, immersed in a Dirac sea. This work analytically tackles a spin-valley Anderson impurity, featuring a general (anti-)Hund's interaction ($J_D, J_S$) that can originate from electron-phonon couplings. We derive its full phase diagram, which encompasses rich continuous local phase transitions, and presents a unified origin for pairing potential and pseudogap. In particular, $J_D$ favors a valley doublet, and we show it drives a BKT transition out of heavy Fermi liquid, to an anisotropic doublet phase exhibiting a non-analytic zero-energy kink in the impurity spectral function. $J_S$ drives a second-order transition out of heavy Fermi liquid, to a local singlet phase, with a non-Fermi liquid critical point. We analyze the pairing potential across the phase diagram, and unveil their ubiquitous existence triggered by the (anti-)Hund's multiplet splitting. Crucially, we show the pseudogap shoulders in the spectral function represent multiplet excitations induced by an injected electron or hole. All results are obtained analytically, using techniques including bosonization-refermionization, with further verification by numerical renormalization group calculations. Then we derive the correlation self-energy ansatze that account for pseudogap, and apply to the magic-angle graphene lattice.
format Preprint
id arxiv_https___arxiv_org_abs_2510_23604
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Spin-Valley Anderson Impurity for Moiré Systems: Fermi Liquid, Pairing, and Pseudogap
Wang, Yi-Jie
Zhou, Geng-Dong
Jung, Hyunsung
Youn, Seongyeon
Lee, Seung-Sup B.
Song, Zhi-Da
Strongly Correlated Electrons
Recent experiments support that the magic-angle graphene can be modeled by a periodic array of correlated quantum impurities, immersed in a Dirac sea. This work analytically tackles a spin-valley Anderson impurity, featuring a general (anti-)Hund's interaction ($J_D, J_S$) that can originate from electron-phonon couplings. We derive its full phase diagram, which encompasses rich continuous local phase transitions, and presents a unified origin for pairing potential and pseudogap. In particular, $J_D$ favors a valley doublet, and we show it drives a BKT transition out of heavy Fermi liquid, to an anisotropic doublet phase exhibiting a non-analytic zero-energy kink in the impurity spectral function. $J_S$ drives a second-order transition out of heavy Fermi liquid, to a local singlet phase, with a non-Fermi liquid critical point. We analyze the pairing potential across the phase diagram, and unveil their ubiquitous existence triggered by the (anti-)Hund's multiplet splitting. Crucially, we show the pseudogap shoulders in the spectral function represent multiplet excitations induced by an injected electron or hole. All results are obtained analytically, using techniques including bosonization-refermionization, with further verification by numerical renormalization group calculations. Then we derive the correlation self-energy ansatze that account for pseudogap, and apply to the magic-angle graphene lattice.
title Spin-Valley Anderson Impurity for Moiré Systems: Fermi Liquid, Pairing, and Pseudogap
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2510.23604