TB or not TB? Contrasting properties of twisted bilayer graphene and the alternating twist $n$-layer structures ($n=3, 4, 5, \dots$)

TL;DR

This paper compares twisted bilayer graphene and multilayer structures with alternating twists, revealing how external fields and relaxation affect their electronic properties and potential for hosting exotic phases.

Contribution

It provides a comprehensive analysis of alternating twist multilayer graphene, highlighting differences from TBG and identifying optimal conditions for fractional Chern insulators.

Findings

External fields affect ATMG and TBG differently based on layer number.

The second magic angle for n=5 layers is close to the chiral model, favoring fractional Chern insulators.

In-plane magnetic fields can induce phase transitions and enhance critical fields beyond Pauli limits.

Abstract

The emergence of alternating twist multilayer graphene (ATMG) as a generalization of twisted bilayer graphene (TBG) raises the question - in what important ways do these systems differ? Here, we utilize ab-initio relaxation and single-particle theory, analytical strong coupling analysis, and Hartree-Fock to contrast ATMG with $n=3,4,5,\ldots$ layers and TBG. $\textbf{I}$: We show how external fields enter in the decomposition of ATMG into TBG and graphene subsystems. The parallel magnetic field has little effect for $n$ odd due to mirror symmetry, but surprisingly also for any $n > 2$ if we are are the largest magic angle. $\textbf{II}$: We compute the relaxation of the multilayers leading to effective parameters for each TBG subsystem. We find that the second magic angle for $n=5$, $\theta = 1.14$ is closest to the "chiral" model and thus may be an optimal host for fractional Chern insulators. $\textbf{III}$: We integrate out non-magic subsystems and reduce ATMG to its magic angle TBG subsystem with a screened interaction. $\textbf{IV}$: We perform an analytic strong coupling analysis of the external fields and corroborate it with Hartree-Fock. An in-plane magnetic field in TBG drives a transition to a valley Hall state or a gapless "magnetic semimetal." A displacement field $V$ has little effect on TBG, but induces a gapped phase in ATMG for small $V$ for $n = 4$ and above a critical $V$ for $n = 3$. For $n\geq 3$, we find the superexchange coupling - believed to set the scale of superconductivity in the skyrmion mechanism - increases with $V$ at angles near and below the magic angle. $\textbf{V}$: We complement our strong coupling approach with a weak coupling theory of ATMG pair-breaking. While for $n=2$ orbital effects of the in-plane magnetic field can give a critical field of the same order as the Pauli field, for $n>2$ we expect the critical field to exceed the Pauli limit.