Exchange-frustrated quadrupoles on the honeycomb lattice: Flavor-wave spectra, classical degeneracies and parton constructions

Abstract

We study the quadrupolar Kitaev model, an S=1 honeycomb-lattice model with frustrated bond-dependent quadrupolar interactions. Using complementary methods and expanding around controlled limits, we uncover several intertwined structures. First, a semiclassical variational analysis based on SU(3) flavor theory reveals an extensively degenerate manifold of classical mean-field ground states, suggesting that quantum fluctuations may stabilize a quantum-disordered phase. Second, in the bond-anisotropic limit, perturbation theory is used to derive effective low-energy Hamiltonians, which crucially depend on the presence (or absence) of a residual symmetry M of combined lattice reflection and discrete spin rotation. A Majorana parton construction uncovers an exact Z2 gauge structure and motivates possible confined and deconfined phases driven by gauge-charge condensation, consistent with the effective theories obtained in anisotropic limit. Further, within the same parton formalism, different Majorana mean-field ans\"atze produce both gapless and gapped candidate quantum-disordered states, distinguished by linear versus projective implementations of M. Our results highlight frustrated quadrupolar interactions as a route to quantum-disordered phases, relevant to S ≥ 1 Kitaev materials and Rydberg-array quantum simulators.