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We present a theoretical investigation of the magnetic properties exhibited by twisted bilayer graphene systems with small twist angles, where the appearance of flat minibands strongly enhances electron-electron interaction effects. We consider a tight-binding Hamiltonian combined with a Hubbard mean-field interaction term and employ a real-space recursion technique to self-consistently calculate the system's local density of states. The O (N) efficiency of the recursion method makes it possible to address superlattices of very large size by means of a full real-space analysis. Our procedure is validated by comparison with literature momentum-space calculations that find a magnetic phase in charge-neutral twisted bilayer graphene. We use our method to investigate the properties of small-angle twisted bilayer graphene at three-quarters filling of the conduction miniband. Our calculations indicate the emergence of a ferromagnetic phase that can be understood in terms of the Stoner mechanism, in line with recent experimental observations.
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