Thermal conductivity of IPA-CuCl3: Evidences of ballistic magnon transport and limited applicability of the Bose-Einstein condensation model

Abstract

The heat transport of the spin-gapped material (CH3)2CHNH3CuCl3 (IPA-CuCl3), a candidate quantum magnet with Bose-Einstein condensation (BEC), is studied at ultra-low temperatures and in high magnetic fields. Due to the presence of the spin gap, the zero-field thermal conductivity () is purely phononic and shows a ballistic behavior at T < 1 K. When the gap is closed by magnetic field at H = Hc1, where a long-range antiferromanetic (AF) order of Cu2+ moments is developed, the magnons contribute significantly to heat transport and exhibit a ballistic T3 behavior at T < 600 mK. In addition, the low-T (H) isotherms show sharp peaks at Hc1, which indicates a gap re-opening in the AF state (H > Hc1) and demonstrates limited applicability of the BEC model to IPA-CuCl3.