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Motivated by the recent experimental study on a quantum Ising magnet K₂Co (SeO₃) ₂ where spectroscopic evidence of zero-field supersolidity is presented arXiv: 2402. 15869, we simulate the excitation spectrum of the corresponding microscopic XXZ model for the compound, using the recently developed excitation ansatz of infinite projected entangled-pair states (iPEPS). We map out the ground state phase diagram and compute the dynamical spin structure factors across a range of magnetic field strengths, focusing especially on the two supersolid phases found near zero and saturation fields. Our simulated excitation spectra for the zero-field supersolid "Y" phase are in excellent agreement with the experimental data -- recovering the low-energy branches and integer quantized excited energy levels ₙ=nJₙₙ. Furthermore, we demonstrate the nonlocal multi-spin-flip features for modes at ₂, indicative of their multi-magnon nature. Additionally, we identify characteristics of the high-field supersolid "V" phase in the simulated spectra, to be compared with future experimental results.
Xu et al. (Wed,) studied this question.