Low-temperature thermal conductivity of Dy2Ti2O7 and Yb2Ti2O7 single crystals

Abstract

We study the low-temperature thermal conductivity () of Dy2Ti2O7 and Yb2Ti2O7 single crystals in magnetic fields up to 14 T along the [111], [100] and [110] directions. The main experimental findings for Dy2Ti2O7 are: (i) the low-T (H) isotherms exhibit not only the step-like decreases at the low-field (< 2 T) magnetic transitions but also obvious field dependencies in high fields (> 7 T); (ii) at T 0.5 K, the (H) curves show anisotropic irreversibility in low fields, that is, the (H) hysteresis locates at the first-order transition with H [100] and [110], while it locates between two successive transitions with H [111]; (iii) the in the hysteresis loops for H [100] and [110] show an extremely slow relaxation with the time constant of 1000 min. The main experimental findings for Yb2Ti2O7 are: (i) the zero-field (T) show a kink-like decrease at the first-order transition ( 200 mK) with decreasing temperature; (ii) the low-T (H) isotherms show a decrease in low field and a large enhancement in high fields; (iii) the low-T (H) curves show a sharp minimum at 0.5 T for H [110] and [111]. The roles of monopole excitations, field-induced transitions, spin fluctuations and magnetoelastic coupling are discussed.