Phase Diagram and Spectroscopic Signatures of a Supersolid in Quantum Ising Magnet K2Co(SeO3)2

Abstract

A supersolid is a quantum-entangled state of matter exhibiting the dual characteristics of superfluidity and solidity. Theory predicts that hard-core bosons with repulsive interactions on a triangular lattice can form supersolid phases at half filling and near complete filling. Leveraging an exact mapping between bosons and spin-12 degrees of freedom, we investigate these phases in the spin-12 triangular-lattice antiferromagnet 212 with exchange constants Jz = 2.96(2)~meV and J = 0.21(3)~meV. At zero field, neutron diffraction reveals the gradual development for T<15~K of quasi-two-dimensional 3×3 magnetic order with Z3 translational symmetry breaking (solidity) albeit with 44(5)% reduced amplitude at T=0.3~K indicating strong quantum fluctuations. These are apparent in equidistant bands of continuum neutron scattering for ωn≈ n× Jz, where n=0,1,2,3. The lowest energy (n=0) Q-dependent continuum has a lower resonant edge and includes a quasi-elastic component at K (1313) consistent with broken U(1) spin rotational symmetry (boson superfluidity). Competing instabilities are apparent in soft albeit finite-energy modes at M (120) and at 12K (1616). For c-axis-oriented magnetic fields 17~ T <μ0 H< 21~ T that almost saturate the magnetization, corresponding to nearly filling the lattice with bosons, we find a new phase consistent with a second supersolid. These phases are separated by a pronounced 1/3 magnetization plateau that supports coherent spin waves, from which we determine the spin Hamiltonian.