Large magnetic thermal conductivity induced by frustration in low-dimensional quantum magnets

Abstract

We study the magnetic field-dependence of the thermal conductivity due to magnetic excitations in frustrated spin-1/2 Heisenberg chains. Near the saturation field, the system is described by a dilute gas of weakly-interacting fermions (free-fermion fixed point). We show that in this regime the thermal conductivity exhibits a non-monotonic behavior as a function of the ratio α= J2/J1 between second and first nearest-neighbor antiferromagnetic exchange interactions. This result is a direct consequence of the splitting of the single-particle dispersion minimum into two minima that takes place at the Lifshitz point α=1/4. Upon increasing α from zero, the inverse mass vanishes at α=1/4 and it increases monotonically from zero for α ≥ 1/4. By deriving an effective low-energy theory of the dilute gas of fermions, we demonstrate that the Drude weight K th of the thermal conductivity exhibits a similar dependence on α near the saturation field. Moreover, this theory predicts a transition between a two-component Tomonaga-Luttinger liquid and a vector-chiral phase at a critical value α=αc that agrees very well with previous density matrix renormalization group results. We also show that the resulting curve K th(α) is in excellent agreement with exact diagonalization (ED) results. Our ED results also show that K th(α) has a pronounced minimum at α 0.7 and it decreases for sufficiently large α at lower magnetic field values. We also demonstrate that the thermal conductivity is significantly affected by the presence of magnetothermal coupling.