Self-energy corrections in an antiferromagnet -- interplay of classical and quantum effects on quasiparticle dispersion

Abstract

Self-energy corrections due to fermion-magnon interaction are studied in the antiferromagnetic state of the t-t'-t'' Hubbard model within the rainbow (noncrossing) approximation in the full U range from weak to strong coupling. The role of classical (mean-field) features of fermion and magnon dispersion, associated with finite U,t',t'', are examined on quantum corrections to quasiparticle energy, weight, one-particle density of states etc. A finite-U induced classical dispersion term, absent in the t-J model, is found to play an important role in suppressing the quasiparticle weight for states near k=(0,0), as seen in cuprates. For intermediate U, the renormalized AF band gap is found to be nearly half of the classical value, and the weak coupling limit is quite non-trivial due to strongly suppressed magnon amplitude. For finite t', the renormalized AF band gap is shown to vanish at a critical interaction strength Uc, yielding a spin fluctuation driven first-order AF insulator - PM metal transition. Quasiparticle dispersion evaluated with the same set of Hubbard model cuprate parameters, as obtained from a recent magnon spectrum fit, provides excellent agreement with ARPES data for Sr2 Cu O2 Cl2 .

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