Classical ground states, spin-wave and PCUT analysis of H2SQ system

Abstract

We study an organic Hydrogen bonded material H2SQ analytically and map out the phase diagram as well as low energy excitations in the relevant parameter space. At zeroth order the dynamics is governed by plaquette interaction (product of σz over a plaquette) which defines a Z2 gauge theory and a deconfinement phase satisfying "ice rules". The system is studied under additional interactions such as an external Zeeman field (with strength K) in x-direction, a inter-molecular interaction (with strength J1) and a dipole-dipole interaction with strength J2 such that K>J1>J2. The effect of dipole-dipole interaction removes the local Z2 symmetry and gives rise to four global degenerate states with Ferroeletric order. Using meanfield analysis we chart out the phase diagram for classical version of the model and find Kc which defines the transition from disordered phase to ordered phase in J1, K plane for various values of J2. We find that presence of J1 and J2 tends to stabilize the deconfined phases. Over the classical ground states we perform spin-wave analysis and surprisingly find that quantum fluctuations does not remove the classical degeneracy at all at quadratic level. The spin-wave spectrum is found for the four global degenerate ground states which shows both gapped spectrum and gapless spectrum (near the vicinity of CDT transition) for J2=0. However for J2 finite, the spectrum is always gapped. We perform PCUT analysis to improve the results of spin-wave analysis and calculate ground state energy and one particle dispersion and gap at high symmetry point. Using this we draw the phase boundary between confined and deconfined phase in the K-J1 plane. The effect of J2 is also discussed in the resulting phase boundary.