Gapless Spin Liquid Behavior in A Kagome Heisenberg Antiferromagnet with Randomly Distributed Hexagons of Alternate Bonds

Abstract

We demonstrate that the new single crystal of YCu3[OH(D)]6.5Br2.5 (YCOB) is a kagome Heisenberg antiferromagnet (KHA) without evident orphan spins ( 0.8\%). The site mixing between polar OH- and non-polar Br- causes local distortions of Cu-O-Cu exchange paths, and gives rise to 70(2)\% of randomly distributed hexagons of alternate bonds ( J1- J and J1+ J) and the rest of almost uniform hexagons ( J1) on the kagome lattice. Simulations of the random exchange model with J/J1 = 0.7(1) show good agreement with the experimental observations, including the weak upturn seen in susceptibility and the slight polarization in magnetization. Despite the average antiferromagnetic coupling of J1 60 K, no conventional freezing is observed down to T 0.001J1, and the raw specific heat exhibits a nearly quadratic temperature dependence below 1 K 0.02J1, phenomenologically consistent with a gapless (spin gap ≤ 0.025J1) Dirac quantum spin liquid (QSL). Our result sheds new light on the theoretical understanding of the randomness-relevant gapless QSL behavior in YCOB, as well as in other relevant materials.