Magnetism of the s=1/2 J1-J2 square-kagome lattice antiferromagnet

Abstract

The spin-1/2 Heisenberg antiferromagnet on the square-kagome (SK) lattice has attracted growing attention as a model system of highly frustrated quantum magnetism. A further motivation for theoretical studies comes from the recent discovery of SK spin-liquid compounds. The SK antiferromagnet exhibits two non-equivalent nearest-neighbor bonds J1 and J2. One may expect that in SK compounds J1 and J2 are of different strength. We present a numerical study of finite systems by means of the finite-temperature Lanczos method. We discuss the temperature dependence of the specific heat C(T), the entropy S(T), and of the susceptibility X(T) of the J1-J2 SK Heisenberg antiferromagnet varying J2/J1 in the range 0 J2/J1 4. We also discuss the zero-field ground state of the model. We find indications for a magnetically disordered singlet ground state for 0 J2/J1 1.65. Beyond J2/J1 1.65 the singlet ground state gives way for a ferrimagnetic ground state. In the region 0.77 J2/J1 1.65 the low-temperature thermodynamics is dominated by a finite singlet-triplet gap filled with low-lying singlet excitations leading to an exponentially activated low-temperature behavior of X(T). On the other hand, the low-lying singlets yield an extra maximum or a shoulder-like profile below the main maximum in the C(T) curve. For J2/J1 0.7 the low-temperature thermodynamics is characterized by a large fraction of N/3 weakly coupled spins leading to a sizable amount of entropy at very low temperatures. In an applied magnetic field the magnetization process features plateaus and jumps in a wide range of J2/J1.

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