Abstract
An exact mapping between quantum spins and boson gases provides fresh approaches to the creation of quantum condensates and crystals. Here we report on magnetization measurements on the dimerized quantum magnet SrCu2(BO3)2 at cryogenic temperatures and through a quantum-phase transition that demonstrate the emergence of fractionally filled bosonic crystals in mesoscopic patterns, specified by a sequence of magnetization plateaus. We apply tens of Teslas of magnetic field to tune the density of bosons and gigapascals of hydrostatic pressure to regulate the underlying interactions. Simulations help parse the balance between energy and geometry in the emergent spin superlattices. The magnetic crystallites are the end result of a progression from a direct product of singlet states in each short dimer at zero field to preferred filling fractions of spin-triplet bosons in each dimer at large magnetic field, enriching the known possibilities for collective states in both quantum spin and atomic systems.
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Introduction
The condensation of a gas of identical, non-interacting bosons—fundamental particles with integer spin—into the lowest energy level represents a canonical demonstration of emergent quantum behaviour. This phenomenon has been observed in a wide range of physical systems, ranging from superfluidity in helium-41 to dilute gases of cold atoms2, and is now known as Bose–Einstein condensation (BEC) after the pioneering quantum statistical predictions of 1924. BEC effects also can be induced in fermionic materials such as helium-3, where particles of half-integer spin form bound pair states, which then condense at low temperatures3,4. Surprisingly, quantum magnets can fulfil this prescription, where an analogy is drawn between a spin 1/2 dimer system in an external magnetic field H and a lattice gas of hard-core bosons5,6,7,8. We show here that it is not only possible to crystallize the quantum spins of the model two-dimensional (2D) magnet SrCu2(BO3)2, composed of sheets of Cu2+ spin 1/2 dimers on a square lattice, into mesoscopic bosonic patterns under the influence of large magnetic fields, but also to tune these patterns with hydrostatic pressure.
At H=0, pairs of antiferromagnetically coupled S=1/2 spins can dimerize to form effective spins with an S=0 ground state and an S=1 excited state separated by an energy gap Δ. When an external magnetic field is applied, the Zeeman effect breaks the degeneracy of the triplet state and suppresses the energy gap between the ground state and the lower branch of the excited state at a critical field Hc=Δ/gμB, where g is the electron g-factor and μB is the Bohr magneton (Fig. 1a). Dimers in the singlet ground state map to an unoccupied lattice site, while those in the excited triplet state correspond to a boson occupying a lattice site. Above Hc, the gap is closed and a finite density of bosons can be sustained even at zero temperature, thus enabling the possibility of a BEC.
Physical realizations of dimerized spin systems typically have both inter- and intra-dimer interactions. These interactions map to repulsive and hopping terms, respectively, in the bosonic picture, with the applied field acting as the chemical potential. Systems where the spin topology leads to magnetic frustration exhibit reduced kinetic energy, and the triplets will then minimize the repulsive interactions by crystallizing. The resulting Wigner crystal can be characterized by the fractional filling factor of bosons on a superlattice. Here we tune the magnetic field to favour different superlattice filling factors along with applying hydrostatic pressure to regulate the underlying dimer interactions in a 2D quantum magnet, including passage through a quantum-phase transition, demarcating singlet physics and stripe order. Numerical simulations confirm the identities of the different states that emerge with the shifting balance of inter- and intra-dimer exchange interactions. The internal structure, energetic stability and evolution of the different superlattice states with pressure and field illuminate the collective dynamics of highly frustrated quantum spin systems.
The primary observable, both in experiment and in numerical simulations, is the overall magnetization M, expressed in normalized units as m ≡ M/Msat where Msat is the saturation moment, corresponding to all spins aligned with the applied field. When crystallization occurs, a gap opens in the excitation spectrum, and the boson density remains unchanged until the system transitions into a new phase. The magnetization fraction m of the corresponding magnetization plateau directly yields the filling factor. The topology we study here is the Shastry–Sutherland model9, a planar array of S=1/2 spins coupled by a network of nearest-neighbour (NN), J, and next-nearest-neighbour (NNN) interactions, J′, (Fig. 1b) with Hamiltonian
The ground-state spin configuration depends on the relative values of J and J′. For small x ≡ J′/J, the ground state is a collection of interacting singlet states on each dimer. There is a quantum-phase transition into an intermediate short-range-ordered state of antiferromagnetic plaquettes at x∼0.69, followed by a second transition into a Néel antiferromagnet at x∼0.8. The sensitivity of the dimer energy gap Δ on x makes the Shastry–Sutherland topology a valuable substrate for studying emergent bosonic superstructures, as it offers the ability to independently tune the interaction energy (via x) and the chemical potential (that is, the magnetic field H).
The layered spin-dimer material SrCu2(BO3)2 (SCBO) is an experimental realization of the Shastry–Sutherland model10,11,12,13, with x estimated to lie between 0.6 and 0.64 at ambient pressure13,14, and a measured singlet–triplet gap energy Δ=3 meV (ref. 15). The magnetization plateaus characteristic of bosonic crystallization emerge for H>20 T, first at filling fractions m=1/8, 1/4 and 1/3, and subsequently at intermediate fillings 2/15 and 1/6 for temperatures below ∼0.8 K (refs 6, 11, 16, 17, 18, 19). Recent magnetostriction measurements at fields up to 118 T have seen indications of m=2/5 and 1/2 plateaus20,21. Although clearly demonstrating bosonic crystallization in a quantum magnet, the exact spin configurations in the low-field plateau states remain a matter of debate11,16,17,18,19,20,21,22,23.
Tuning the other major variable in the problem, the dimer interaction ratio x ≡ J′/J, offers the possibility of further insights into the plethora of high-field collective states. Hydrostatic pressure tunes x across the phase diagram, with a continuous quantum-phase transition into the plaquette state at P∼2 GPa (refs 24, 25, 26, 27), followed by long-range antiferromagnetic order and an associated symmetry-breaking structural transition at P∼4.5 GPa (refs 28, 29). SCBO remains effectively 2D for pressures below this structural transition, at which point the Cu–Cu dimers tilt out of the plane28.
By varying P and sweeping H, we systematically study the bosonic crystal against a backdrop of different underlying spin states, controlling the strength of the kinetic and repulsive energies, as well as the overall chemical potential. To that end, we performed magnetization measurements on high-quality single crystals of SCBO in a piston cylinder cell for pressures up to 2.2 GPa, magnetic fields up to 34 T and temperatures down to 350 mK.
Results
High-field magnetization at ambient pressure
Due to the small sample volumes available in the pressure cell, we employed a high-sensitivity tunnel diode oscillator (TDO) technique30 to measure the magnetization. The crystal is placed inside the inductor component of a diode-biased self-resonant LC tank circuit and changes in the sample magnetization lead to changes in the circuit resonant frequency f (Supplementary Figs 1,2). We plot in Fig. 1c the variation of the TDO resonant frequency with external magnetic field (df/dH) at T=0.35 K for a range of pressures, where df/dH ∝ dM/dH, the magnetic susceptibility of the sample. The magnetic field was applied parallel to the c axis of the crystal. At ambient pressure, an anomaly is clearly visible at Hc1∼27 T that corresponds to the m=1/8 plateau observed in previous experiments16,17,18 and in our own P=0 torque magnetometry measurements (Supplementary Fig. 3), with no hysteresis detected between field up and down trajectories. The ∼2 T distance between the two extrema in the anomaly indicates the range of magnetic field at which the m=1/8 triplet superlattice phase exists. Nuclear magnetic resonance17,19 and magnetostriction18,20,21 measurements found that the superlattice states of highly magnetized triplet dimers persist adjacent to the 1/8 plateau for fields up to ∼30 T. These states may account for the skewed line shape of the maximum observed above Hc1 in Fig. 1c.
High-field magnetization at high pressure
The magnetic susceptibility responds sensitively to pressure, where the 2.2 GPa maximum P in Fig. 1c corresponds to ∼10% increase in x, with Pc=1.93±0.07 GPa (refs 24, 31, 32). For P<Pc, the continuous increase in x and consequent decrease in Δ drives the feature marking the m=1/8 superlattice plateau to lower field, with Hc1 at only 2/3 of its P=0 value by 1.7 GPa. Crossing Pc changes the response not only quantitatively, but qualitatively as well. Instead of a single feature at Hc1 corresponding to the m=1/8 filling, we observe a total of three features, which we denote as Hc2 at 33 T, Hc3 at 18 T and Hc4 at 7 T. By pressure tuning the H=0 spin configuration into a different ground state, we enable a different set of high-field magnetic superlattice states to emerge.
Temperature dependence of magnetization at different pressures
We now turn to the question of the energetics and microstructure of these new states. We plot in Fig. 2 the temperature dependence of the susceptibility both below and above Pc. At ambient pressure, the signature of the m=1/8 plateau is suppressed with increasing T and is no longer detected at 1.8 K (Fig. 2a), comparable to prior measurements11,17,18. The new anomalies in the high-pressure state are also suppressed by T=1.8 K (Fig. 2b), where the spin superlattices of different m apparently melt. The associated values of the critical fields remain fixed over the entire temperature range, indicating that the amplitudes of the spin-density modulations are independent of T.
Density matrix renormalization group calculation
To elucidate the spin structures in both the low P, singlet and the high P, plaquette states, we compare the experimental results with numerical calculations performed on an ideal Shastry–Sutherland lattice over a range of x. We calculate M(H) using a density matrix renormalization group (DMRG) approach on finite lattices of 8 × 8, 10 × 10 and 16 × 8 spins for x ≡ J′/J≈0.6, 0.63 and 0.7 with cylindrical boundary conditions (Supplementary Fig. 4). We found that this choice is less vulnerable to boundary effects, and is similar to the one employed in previous studies.20
We plot in Fig. 3, the calculated singlet–triplet gap Δ (red) and the critical field for the m=1/8 plateau (green), as a function of x=J′/J for an 8 × 8 lattice with cylindrical boundary conditions. We show the experimentally measured pressure evolution of Hc1 (blue) on the lower axis, mapped to x on the upper axis24,31,32. Hc1 for the m=1/8 plateau continuously decreases with increasing P, as the gap between the lowest triplet excitation branch and the singlet state decreases. The correspondence between the calculated and the measured values confirms the connection between Hc1 and the suppression of the singlet–triplet gap Δ, and further, serves as a consistency check between the numerical results and the experimental data, with no free parameters in the comparison (Supplementary Fig. 5).
The calculated magnetization curves merge as a function of increased system size (Supplementary Fig. 4). We plot in Fig. 4a, the magnetization curves obtained using DMRG calculations for an 16 × 8 spin lattice with cylindrical boundary conditions for x=0.6 (blue) and 0.7 (red). These serve to represent the singlet and plaquette ground states, respectively31,32. New plateaus emerge for x=0.7, with a pronounced shift to lower H. While the resolution limits of the numerics are not sufficient to assign precise filling fractions to all of the plateaus seen in the calculation, the magnetization curve captures the essential features observed in the experimental data of Fig. 1c, including the emergence at P=2.2 GPa (x=0.7) of new anomalies at Hc4∼7 T and Hc3∼15 T. These results indicate that for x=0.7, the normalized magnetizations associated with Hc3 and Hc4 converge to filling factors of ∼1/10 and ∼1/20, both smaller than m=1/8, the lowest plateau seen for x=0.6 in the calculations and for P<2 GPa in the experiment.
Discussion
To explore the nature of the new magnetization profile, we performed DMRG simulations at fixed magnetization Sz on lattices with different aspect ratios, keeping up to 3,000 DMRG states, corresponding to a truncation error of order 10−5 or smaller for the system sizes considered (Supplementary Fig. 6). We followed a zigzag path along the diagonal bonds of the square lattice, taking advantage of the strong entanglement along these links. The simulations are done on a conventional square lattice with open boundary conditions to avoid a bias towards magnetization profiles that break the 90° rotational symmetry of the lattice. We introduced a small pinning field at the site (x, y)=(Lx, Ly), where L is the linear dimension of the lattice, to resolve the spatial magnetization profile of the structure that has maximum susceptibility in a finite-size system, removing this field in the last series of iterations. For x=0.63 and a 16 × 8 lattice, we found a ground-state energy per site of E0=−0.3478 for Sz=16 (corresponding to m=1/8). This value lies close to, but slightly above the extrapolation to the thermodynamic limit, E0=−0.3475 that was obtained by Corboz et al.22 using infinite projected entangled-pair states (iPEPS), a tensor-network method, for a structure formed by bound states of triplets. We note that the ground-state energy is expected to be higher for a finite system, due in part to the potential mismatch in aspect ratios between the finite lattice and the optimal magnetic structure.
We present in Fig. 4b,c schematics of the magnetization profiles, corresponding to the Hc1 and Hc3,c4 plateaus mapped onto a real-world realization of the Shastry–Sutherland lattice, and computed for 16 × 8 and 8 × 8 spin lattices with open boundary conditions along both directions, respectively. The magnetization profile at Hc1, (Fig. 4b) is consistent with the iPEPS results22, and suggests the crystallization of Sz=2 triplet bound states, which form a ‘pinwheel’ pattern on a square supercell at the m=1/8 plateau. This agreement between the DMRG and iPEPS results is remarkable considering the unbiased nature of the DMRG approach. By contrast, the magnetization profiles obtained at Hc3 and Hc4 point to the likelihood of field-induced stripe ordering (Fig. 4c). The emergence of low-magnetization stripe-ordered magnetic superstructures indicates that the pressure-tuned increase in the kinetic energy of the triplets, eventually could lead to their full condensation into a long-range-ordered antiferromagnet. Stripe structures are also proposed to appear for higher-magnetization pleateaus, m=2/15, 1/6 and 1/4 at ambient pressure22. The full nature of these states will require further theoretical investigation, including the need to understand the role of spin–lattice coupling33 and anisotropic Dzyaloshinskii–Moriya interactions28,34.
The plateau at Hc2 behaves differently than those at Hc3 and Hc4 in that it initially emerges in the experiment for P<Pc. The m=1/4 state satisfies this criterion, being present in the simulations for both x=0.6 and 0.7. Filling factor 1/4 is believed to be especially stable17,18,19,20,21, and we posit that this superlattice state exists over the full range of the singlet and plaquette phases that we probe, moving into our experimental magnetic field window at 1.7 GPa and continuing to shift to lower H with increasing P. The stability of Hc2 at m=1/4 contrasts with that of the Hc1 plateau at m=1/8 that no longer persists across the quantum-phase transition at Pc.
One of the long-standing mysteries of SCBO is the existence of bosonic crystals at m values as low as 1/8. As the Shastry–Sutherland model only has bare repulsive interactions between NN and NNN, low-density structures such as m=1/8, where the average distance between bosons is significantly larger than the distance between NN and NNN, are not expected to appear. Consequently, one can ask what is the origin of the longer length scale that determines the crystallization at m=1/8 and lower concentrations? One plausible explanation is given by the formation of triplet bound states. In this picture, the missing length scale is lB, the mean separation between the two Sz=2 triplets in the bound state (analogous to the coherence length for Cooper pairs). The crystallization can now occur at low triplet concentrations because the effective size of the triplet pair (composite particle) can be large.
The effect of pressure on the dimer singlet interactions in SCBO straightforwardly tunes the ground state at H=0, consonant with the original Shastry–Sutherland picture. More surprisingly, the crystallization of spin-triplet bosons at high magnetic field also appears to be highly malleable. As applied, pressure increases x ≡ J′/J and drives the dimers into the quantum-phase transition, it increases the single–triplet kinetic energy, and thereby increases the linear size lB of Sz=2 triplet pair bound states. The crystallization of triplet bound states explains the emergence of low-magnetization plateaus, such as m≤1/8, for which the average inter-triplet distance da=m−1/2 is significantly bigger than the range of the repulsive bare interactions. Triplet bound states start ‘seeing each other’ when lB becomes comparable to da. The increase of lB with pressure could explain the new pressure-induced low-magnetization plateaus (m<1/8) that we are reporting here. In this picture, the pairs of triplet bound states are forming larger composite particles under pressure and thus interact at lower m concentrations.
Methods
Single-crystal growth
Single-crystal samples of SrCu2(11BO3)2 were cut from the same high-quality parent single crystal employed in previous experiments15,18,20,24,26, grown in a floating zone image furnace at a rate of 0.2 mm h−1 in an O2 atmosphere35.
High-pressure magnetization
The sample’s magnetization as a function of field, temperature and pressure was determined in a 35 T resistive magnet at the National High Magnetic Field Laboratory using a 3He cryostat with a base temperature of 350 mK and a piston cylinder cell (PCC) (Supplementary Fig. 1). The cell body was made from MP35N, an alloy with a strength ∼1,800 MPa, considerably larger than that of BeCu (∼1,200 MPa). The sample platform was immersed in a polytetrafluoroethylene (PTFE) cup filled with Daphne 7474 oil as a pressure medium36. A transducer was used to accurately monitor the load that was applied to the PCC before tightening the top clamp of the cell. The pressure in the sample chamber was measured using ruby fluorescence37 at room temperature and at ∼2 K to account for any variation in pressure during the cooling process. The pressure cell was immersed directly into 3He to maximize thermal contact. Temperature was measured using a calibrated Cernox thermometer located ∼2 mm from the cell.
Tunnel diode oscillator
TDO measurements were conducted on cylinder-shaped crystals with approximate dimensions of 2 mm in length by 0.5 mm in diameter. Each crystal was mounted inside a detection coil placed in the pressure chamber. The coil forms the inductive component of a TDO circuit38 tuned to operate at a resonant frequency ranging between 10 and 50 MHz (Supplementary Fig. 2). The coil axis and c - axis of the sample were co-aligned with the axis of the pressure cell, parallel to the applied magnetic field. The TDO technique is often used to measure the surface conductivity of metals for measurements of the Fermi surface39, but when used to probe the magnetization of insulating materials, it is sensitive to changes in the magnetic moment ∼10−12 e.m.u., allowing sensitive high-field measurements of samples in the tight confines of a pressure cell.
To validate the TDO measurements, magnetic torque measurements were conducted at ambient pressure, using commercial piezoresistive atomic force microscopy (AFM) cantilevers (Seiko PRC400)40. A 200 × 200 × 100 μm3 SCBO crystal was fixed with silicone grease to the end of the 400-μm long cantilever arm. A piezoresistive element at the opposite end of the cantilever senses the deflection of the arm. An additional piezoresistive element on the same cantilever assembly, along with two adjustable external resistors, forms a Wheatstone bridge that was balanced to provide a null signal at zero magnetic field. Changes in sample magnetization induce a torque on the cantilever, resulting in a voltage across the bridge. Supplementary Fig. 3 compares our TDO (red) and magnetic torque measurements (blue) at ambient pressure. The plateau at ∼27 T in the torque magnetometry measurement agrees well in field scale with the feature seen in the TDO data. This plateau is known to correspond to m=M(H)/Msat=1/8 (refs 16, 17, 18).
Density matrix renormalization group
To check for finite-size effects, DMRG calculations of normalized magnetization curves were performed on lattices of 8 × 8, 10 × 10 and 16 × 8 spins with cylindrical boundary conditions for x ≡ J′/J=0.6 and 0.63, and for x=0.7, corresponding to the singlet and plaquette states, respectively. Supplementary Fig. 3 includes the normalized magnetization curve m=M(H)/Msat calculated for x=0.63 using the DMRG method for a 16 × 8 lattice, showing the correspondence in field scale between the calculated m=1/8 plateau, and the observed feature in torque magnetometry and TDO measurements on SCBO at ambient pressure.
As shown in Supplementary Fig. 4, the magnetization curves merge as a function of system size, with qualitative differences between the two families of curves for x=0.6 and 0.7, as would be expected from the differing ground states. Focusing on the m<1/3 regime, large steps are visible in small lattices, indicating that some values of the magnetization are not stable, likely due to incommensuration effects.
We show in Supplementary Fig. 5, the calculated singlet–triplet gap for an 8 × 8 lattice with cylindrical boundary conditions, as a function of x and the energy for Sz=8 (corresponding to m=1/8). Both quantities decrease with increasing x, showing that the energy required to form the 1/8 plateau in SCBO decreases as a function of increasing pressure. The geometry used (Supplementary Fig. 5 inset) was found to be less sensitive to boundary effects and is similar to the one employed in previous studies20.
The DMRG calculations were run keeping up to 3,000 states, giving an upper bound on the truncation error of order 10−5. We plot in Supplementary Fig. 6, the ground-state energy per lattice site (E/N) as a function of the number of DMRG states (m), calculated for an 8 × 8 lattice with open boundary conditions for x=0.7 and Sz=6. The results illustrate the energy convergence with increasing number of DMRG states.
Data availability
The data that support the findings of this study are available from the corresponding authors upon request.
Additional information
How to cite this article: Haravifard, S. et al. Crystallization of spin superlattices with pressure and field in the layered magnet SrCu2(BO3)2. Nat. Commun. 7:11956 doi: 10.1038/ncomms11956 (2016).
References
Kapitza, P. Viscosity of liquid helium below the λ-point. Nature 141, 74–74 (1938).
Davis, K. B. et al. Bose-Einstein Condensation in a gas of sodium atoms. Phys. Rev. Lett. 75, 3969–3973 (1995).
Leggett, A. Interpretation of recent results on He3 below 3 mK: a new liquid phase? Phys. Rev. Lett. 29, 1227–1230 (1972).
Regal, C. A., Greiner, M. & Jin, D. S. Observation of resonance condensation of fermionic atom pairs. Phys. Rev. Lett. 92, 040403 (2004).
Matsubara, T. & Matsuda, H. A lattice model of liquid helium. Prog. Theor. Phys. 16, 569–582 (1956).
Rice, T. M. To condense or not to condense. Science 298, 760–761 (2002).
Giamarchi, T., Rüegg, C. h. & Tchernyshyov, O. Bose-Einstein condensation in magnetic insulators. Nat. Phys. 4, 198–204 (2008).
Zapf, V., Jaime, M. & Batista, C. D. Bose-Einstein condensation in quantum magnets. Rev. Mod. Phys. 86, 1453 (2014).
Shastry, B. S. & Sutherland, B. Exact ground state of a quantum mechanical antiferromagnet. Physica B 108, 1069–1070 (1981).
Smith, R. W. & Keszler, D. A. Synthesis, structure, and properties of the orthoborate SrCu2(BO3)2 . J. Solid State Chem. 93, 430–435 (1991).
Kageyama, H. et al. Exact dimer ground state and quantized magnetization plateaus in the two-dimensional spin system SrCu2(BO3)2 . Phys. Rev. Lett. 82, 3168–3171 (1999).
Miyahara, S. & Ueda, K. Exact Dimer Ground State of the Two Dimensional Heisenberg Spin System SrCu2(BO3)2 . Phys. Rev. Lett. 82, 3701–3704 (1999).
Miyahara, S. & Ueda, K. Thermodynamic properties of three-dimensional orthogonal dimer model for SrCu2(BO3)2 . J. Phys. Soc. Jpn 69, (Supplement B): 72–77 (2000).
Knetter, C., Bühler, A., Müller-Hartmann, E. & Uhrig, G. S. Dispersion and symmetry of bound states in the Shastry-Sutherland Model. Phys. Rev. Lett. 85, 3958–3961 (2000).
Gaulin, B. D. et al. High-resolution study of spin excitations in the singlet ground state of SrCu2(BO3)2 . Phys. Rev. Lett. 93, 267202 (2004).
Kodama, K. et al. Magnetic superstructure in the two-dimensional quantum antiferromagnet SrCu2(BO3)2 . Science 298, 395–399 (2002).
Takigawa, M. et al. NMR evidence for the persistence of a spin superlattice beyond the 1/8 magnetization plateau in SrCu2(BO3)2. Phys. Rev. Lett. 101, 037202 (2008).
Sebastian, S. E. et al. Fractalization drives crystalline states in a frustrated spin system. Proc. Natl Acad. Sci. USA 105, 20157–20160 (2008).
Levy, F. et al. Field dependence of the quantum ground state in the Shastry-Sutherland system SrCu2 (BO3)2 . Euro. Phys. Lett. 81, 67004 (2008).
Jaime, M. et al. Magnetostriction and magnetic texture to 100.75 Tesla in frustrated SrCu2(BO3)2 . Proc. Natl Acad. Sci. USA 109, 12404–12407 (2012).
Matsuda, Y. H. et al. Magnetization of SrCu2(BO3)2 in ultrahigh magnetic fields up to 118 T. Phys. Rev. Lett. 111, 137204 (2013).
Corboz, P. & Mila, F. Crystals of bound states in the magnetization plateaus of the Shastry-Sutherland Model. Phys. Rev. Lett. 112, 147203 (2014).
Ronquillo, D. C. & Peterson, M. R. Identifying topological order in the Shastry-Sutherland model via entanglement entropy. Phys. Rev. B 90, 201108(R) (2014).
Haravifard, S. et al. Continuous and discontinuous quantum phase transitions in a model two-dimensional magnet. Proc. Natl. Acad. Sci. USA 109, 2286–2289 (2012).
Waki, T. et al. A novel ordered phase in SrCu2(BO3)2 under high pressure. J. Phys. Soc. Jpn 76, 073710 (2007).
Sakurai, T. et al. High-field and high-pressure ESR measurements of SrCu2(BO3)2 . J. Phys. Conf. Ser. 150, 042171 (2009).
Zayed, M. et al. Observation of a 4-spin plaquette singlet state in the Shastry-Sutherland compound SrCu2(BO3)2. Preprint at http://arxiv.org/abs/1603.02039 (2016).
Haravifard, S. et al. Emergence of long-range order in sheets of magnetic dimers. Proc. Natl Acad. Sci. USA 111, 14372–14377 (2014).
Zayed, M. et al. Temperature dependence of the pressure induced monoclinic distortion in the spin Shastry Sutherland compound SrCu2(BO3)2 . Solid State Commun. 186, 13–17 (2014).
Clover, R. B. & Wolf, W. P. Magnetic susceptibility measurements with a tunnel diode oscillator. Rev. Sci. Instrum. 41, 617–621 (1970).
Koga, A. & Kawakami, N. Quantum phase transitions in the Shastry-Sutherland Model for SrCu2(BO3)2 . Phys. Rev. Lett. 84, 4461–4464 (2000).
Corboz, P. & Mila, F. Tensor network study of the Shastry-Sutherland model in zero magnetic field. Phys. Rev. B 87, 115144 (2013).
Radtke, G. et al. Magnetic nanopantograph in the SrCu2(BO3)2 Shastry-Sutherland lattice. Proc. Natl Acad. Sci. USA 112, 1971–1976 (2015).
Romhányi, J., Totsuka, K. & Penc, K. Effect of Dzyaloshinskii-Moriya interactions on the phase diagram and magnetic excitations of SrCu2(BO3)2 . Phys. Rev. B 83, 024413 (2011).
Dabkowska, H. A. et al. Crystal growth and magnetic behavior of pure and doped SrCu2(11BO3)2 . J. Cryst. Growth 306, 123–128 (2007).
Murata, K. et al. Pressure transmitting medium Daphne 7474 solidifying at 3.7 GPa at room temperature. Rev. Sci. Instrum. 79, 085101 (2008).
Piermarini, G. J. et al. Calibration of the pressure dependence of the R1 ruby fluorescence line to 195 kbar. J. Appl. Phys. 46, 2774–2780 (1975).
Van Degrift, C. T. Tunnel diode oscillator for 0.001 ppm measurements at low temperatures. Rev. Sci. Instrum. 46, 599–607 (1975).
Graf, D. et al. Pressure dependence of the BaFe2As2 Fermi surface within the spin density wave state. Phys. Rev. B 85, 134503 (2012).
Ohmichi, E. & Osada, T. Torque magnetometry in pulsed magnetic fields with use of a commercial microcantilever. Rev. Sci. Instrum. 73, 3022–3026 (2002).
Acknowledgements
We are grateful to S.W. Tozer for help in acquiring the high-pressure TDO data. The work at the University of Chicago was supported by NSF grant no. DMR-1206519. This research used resources of the Advanced Photon Source, a U.S. Department of Energy Office of Science User Facility operated by Argonne National Laboratory under contract no. NEAC02-06CH11357. The work at the National High Magnetic Field Laboratory was supported by National Science Foundation Cooperative Agreement no. DMR-1157490, the State of Florida, and the U.S. Department of Energy. D.G. acknowledges support from the Department of Energy (DOE) NNSA DE-NA0001979. A.E.F. acknowledges support from NSF under grant DMR-1339564.
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Research conceived and designed by S.H. and T.F.R. Single-crystal SCBO samples grown by S.H., H.A.D. and B.D.G. High-field measurements performed by S.H., D.G. and J.C.L., and analysed by S.H., G.S., D.M.S. and T.F.R. DMRG calculations performed by A.E.F. and C.D.B. Manuscript written by S.H., D.M.S. and T.F.R.; all authors commented on the manuscript.
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Haravifard, S., Graf, D., Feiguin, A. et al. Crystallization of spin superlattices with pressure and field in the layered magnet SrCu2(BO3)2. Nat Commun 7, 11956 (2016). https://doi.org/10.1038/ncomms11956
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DOI: https://doi.org/10.1038/ncomms11956
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