Magnetic phase diagram of the anisotropic multi‐band Hubbard model

Abstract: Using quantum Monte Carlo (QMC) simulations we determine the magnetic phase diagram of the anisotropic two-band Hubbard model within the dynamical mean-field theory (DMFT) in the important intermediate-coupling regime. We compare the QMC predictions with exact results from second-order weakand strong-coupling perturbation theory. We find that the orbital-selective Mott transition (OSMT), which occurs in the fully frustrated case, is completely hidden in the antiferromagnetic (AF) ground state of the model. On … Show more

“…(1) as the J z -model. 28,29,30 A general discussion of the Hund exchange would have to include spin-flip and pair hopping terms, However, such terms are not essential for OSMTs (Ref. 28) and change their character only in the SU (2) symmetric limit J z = J ⊥ ≡ J (i.e., in the Heisenberg limit).…”

“…( 1) as the J z -model. 28,29,30 A general discussion of the Hund exchange would have to include spin-flip and pair hopping terms,…”

“…In this paper, we extend high-precision 35 quantum Monte Carlo (QMC) calculations 28,30,36 within DMFT for two-band model (1) to general doping levels. Of central interest is the phase diagram, which is derived from orbital-dependent fillings, double occupancies, and quasiparticle weights.…”

Orbital-selective Mott transitions in a doped two-band Hubbard model

“…(1) as the J z -model. 28,29,30 A general discussion of the Hund exchange would have to include spin-flip and pair hopping terms, However, such terms are not essential for OSMTs (Ref. 28) and change their character only in the SU (2) symmetric limit J z = J ⊥ ≡ J (i.e., in the Heisenberg limit).…”

“…( 1) as the J z -model. 28,29,30 A general discussion of the Hund exchange would have to include spin-flip and pair hopping terms,…”

“…In this paper, we extend high-precision 35 quantum Monte Carlo (QMC) calculations 28,30,36 within DMFT for two-band model (1) to general doping levels. Of central interest is the phase diagram, which is derived from orbital-dependent fillings, double occupancies, and quasiparticle weights.…”

Orbital-selective Mott transitions in a doped two-band Hubbard model

“…For these new particles, we then define annihilation operators of double occupancies d iσ =c i2σci1σ (with σ =↑, ↓) and d i0 = These results are interesting, because they show that T c is dominated in both models by the largest hopping amplitude, which is that of the broad band (t * 2 ≡ t 2 √ Z). We conclude that the broad band primarily determines the energy scale at strong coupling; from previous work 35 we know that the energy scales of antiferromagnetism at weak coupling are primarily determined by the narrow band (t *…”

“…These results are interesting, because they show that T c is dominated in both models by the largest hopping amplitude, which is that of the broad band (t * 2 ≡ t 2 √ Z). We conclude that the broad band primarily determines the energy scale at strong coupling; from previous work 35 we know that the energy scales of antiferromagnetism at weak coupling are primarily determined by the narrow band (t * 1 ≡ t 1 √ Z). Note that, since the effective strongcoupling Hamiltonians are ∆-independent (within their range of validity), the same holds for the critical temperatures.…”

Orbital-selective Mott transitions in a doped two-band Hubbard model with crystal field splitting