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Displacement-Field-Driven Semimetal-Superconductor Transition in Magic-Angle Twisted Trilayer Graphene

Published 18 Jun 2026 in cond-mat.str-el and cond-mat.supr-con | (2606.20849v1)

Abstract: Magic-angle twisted trilayer graphene(MATTG) hosts versatile displacement-field-tuned correlated phenomena. MATTG consists of a dispersive Dirac cone which hybridizes with the flat band from a twisted bilayer graphene (TBG) sector. The hybridization strength increases with the displacement field $D$ and naively one may expect D-driven heavy fermion physics. However, the TBG Hubbard bands have a momentum-selective Mott gap, which is small at the $Γ$ point due to the band topology, and a rigid local moment description as in the familiar Kondo lattice model is invalid. Here we show that the dominant effect of the displacement field is to induce an energy shift of the Dirac cone and self-doping into the TBG sector. We illustrate this picture in a concrete calculation using a slave-particle theory at the filling $ν=\pm 2$. We find that increasing $D$ drives a transition from a semimetal into a superconducting state. We also discuss the enhancement of the superconductivity by $D$ near $ν=\pm2$ and the particle-hole asymmetry of the phase diagram. Our results provide a unified picture for electric-field-tunable superconductivity, Mottness, and heavy-fermion-like behavior in MATTG.

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