Abstract
The thermodynamic properties of the Shastry-Sutherland model have posed one of the longest-lasting conundrums in frustrated quantum magnetism. Over a wide range on both sides of the quantum phase transition (QPT) from the dimer-product to the plaquette-based ground state, neither analytical nor any available numerical methods have come close to reproducing the physics of the excited states and thermal response. We solve this problem in the dimer-product phase by introducing two qualitative advances in computational physics. One is the use of thermal pure quantum (TPQ) states to augment dramatically the size of clusters amenable to exact diagonalization. The second is the use of tensor-network methods, in the form of infinite projected entangled pair states (iPEPS), for the calculation of finite-temperature quantities. We demonstrate convergence as a function of system size in TPQ calculations and of bond dimension in our iPEPS results, with complete mutual agreement even extremely close to the QPT. Our methods reveal a remarkably sharp and low-lying feature in the magnetic specific heat around the QPT, whose origin appears to lie in a proliferation of excitations composed of two-triplon bound states. The surprisingly low energy scale and apparently extended spatial nature of these states explain the failure of less refined numerical approaches to capture their physics. Both of our methods will have broad and immediate application in addressing the thermodynamic response of a wide range of highly frustrated magnetic models and materials.
Highlights
Frustrated quantum spin systems, those forbidding magnetically ordered ground states, provide one of the most important avenues in condensed matter physics for the realization and investigation of phenomena ranging from fractionalization to many-particle bound states, from massive degeneracy to topological order and from quantum entanglement to quantum criticality [1]
Spectrum of the Shastry-Sutherland model In Fig. 2(a) we showed our collected results for the specific heat of the Shastry-Sutherland model across the range of coupling ratios 0.60 J/JD 0.66
The behavior of the peak height [Fig. 13(b)] is less evident, in that it falls on approach to the quantum phase transition (QPT) in our thermal pure quantum (TPQ) calculations but increases in our infinite projected entangled-pair states (iPEPS) ones, the rate of change accelerating with J/JD in both cases
Summary
Frustrated quantum spin systems, those forbidding magnetically ordered ground states, provide one of the most important avenues in condensed matter physics for the realization and investigation of phenomena ranging from fractionalization to many-particle bound states, from massive degeneracy to topological order and from quantum entanglement to quantum criticality [1]. Data for the specific heat under pressure have appeared concurrently with the present study [24] and indicate that the low-temperature peak moves to a lower temperature at 1.1 GPa before evidence of an ordered phase appears at 1.8 GPa. In contrast to the ground state, the excited states and thermodynamics of the Shastry-Sutherland model are not at all well known around the QPT, despite the attention focused on this regime due to SrCu2(BO3). Our TPQ and finite-T iPEPS methods enable us to capture the physics of the Shastry-Sutherland model, and of SrCu2(BO3), in a way not hitherto possible near the QPT
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