Maple leaf antiferromagnet in a magnetic field

We analyze the quantum antiferromagnet on the maple leaf lattice in the presence of a magnetic field. Starting from its exact dimer ground state and for a magnetic field strength of the order of the local dimer spin-exchange coupling, we perform a strong-coupling expansion and extract an effective hard-core boson model. The interplay of effective many-body interactions, suppressed single-particle dynamics, and correlated hopping gives way to an intriguing series of superfluid to insulator transitions which correspond to magnetization plateaus in terms of the maple leaf spin degrees of freedom. While we find plateaus at intermediate magnetization to be dominated by bosonic density wave order, we conjecture plateau formation from multiboson bound states due to correlated hopping for lower magnetization.

Maple leaf antiferromagnet in a magnetic field

Anomalous‐Chern Steering of Topological Nonreciprocal Guided Waves

Spin-Reorientation-Driven Linear Magnetoelectric Effect in Topological Antiferromagnet Cu3TeO6

Possible restoration of particle-hole symmetry in the 5/2-quantized Hall state at small magnetic field

Anomalous‐Chern Steering of Topological Nonreciprocal Guided Waves

Possible restoration of particle-hole symmetry in the 5/2-quantized Hall state at small magnetic field

Spin-Reorientation-Driven Linear Magnetoelectric Effect in Topological Antiferromagnet Cu3TeO6