Electron-phonon coupling in the topological heavy fermion model of twisted bilayer graphene

On flat bands of the magic-angle twisted bilayer graphene, exotic correlation physics unfolds. Phonons, through mediating an effective electron-electron interaction, can play a crucial role in selecting various electronic phases. In this study, we derive the full electron-phonon coupling (EPC) vertex from the microscopic tight- binding lattice, and identify the significance of each phonon mode. We then project the EPC vertices onto the topological heavy fermion (THF) basis [Z.-D. Song and B. A. Bernevig, Phys. Rev. Lett. 129, 047601 (2022)], and show that an anti-Hund's interaction HA is induced on each moir & eacute;-scale local f orbital, with strengths 1 to 4 meV. We analyze the phonon-induced multiplet splittings, which can significantly affect the local correlation. As an example, we elaborate on the phonon-favored symmetry-breaking orders at even-integer fillings. Through systematic self-consistent Hartree-Fock calculations, we uncover a tight competition between P-phonon-favored orbital orders, K-phonon-favored intervalley coherent orders, and the kinetic and Coulomb-favored orders. Contrary to EPC, the carbon atom Hubbard repulsion induces an on f-site Hund's interaction 1 to 3 meV that partly counteracts the effect of HA. The combined influence of and symmetry-breaking states is discussed. In the end, we explore the possibility of finding an exotic Dirac semimetal formed solely by c electrons at the charge-neutrality point, while f impurities exhibit a symmetric Mott gap by forming nondegenerate singlets under HA,H. Experimental features that distinguish such a state are discussed. HH with strengths HA,H on the multiplet splitting