Frustrated Magnetism of the Maple-Leaf-Lattice Antiferromagnet MgMn3O7·3H2O

Abstract

We present a novel hydrated layered manganate MgMn3O7·3H2O as a maple-leaf-lattice (MLL) antiferromagnet candidate. The MLL is obtained by regularly depleting 1/7 of the lattice points from a triangular lattice so that the magnetic connectivity z = 5 and is thus intermediately frustrated between the triangular (z = 6) and kagom\'e (z = 4) lattices. In MgMn3O7·3H2O, the Mn4+ ions, carrying Heisenberg spin 3/2, form a regular MLL lattice in the quasi-two-dimensional structure. Magnetization and heat capacity measurements using a hydrothermally-prepared powder sample reveal successive antiferromagnetic transitions at 5 and 15 K. A high-field magnetization curve up to 60 T at 1.3 K exhibits a multi-step plateau-like anomaly. We discuss the unique frustration of the MLL antiferromagnet in which the chiraldegree of freedom may play an important role.