Abstract
We report on neutron diffraction, thermal expansion, magnetostriction, dielectric and specific heat measurements on polycrystalline FeCr2S4 in external magnetic fields. The ferrimagnetic ordering temperatures TC ≈ 170 K and the transition at TOO ≈ 10 K, which has been associated with orbital ordering, are only weakly shifted in magnetic fields up to 9 T. The cubic lattice parameter is found to decrease when entering the state below TOO. The magnetic moments of the Cr- and Fe-ions are reduced from the spin-only values throughout the magnetically ordered regime, but approach the spin-only values for fields >5.5 T. Thermal expansion in magnetic fields and magnetostriction experiments indicate a contraction of the sample below about 60 K. Below TOO this contraction is followed by a moderate expansion of the sample for fields larger than ~4.5 T. The transition at TOO is accompanied by an anomaly in the dielectric constant. The dielectric constant depends on both the strength and orientation of the external magnetic field with respect to the applied electric field for T < TOO. A linear correlation of the magnetic-field-induced change of the dielectric constant and the magnetic-field dependent magnetization is observed. This behaviour is consistent with the existence of a ferroelectric polarization and a multiferroic ground state below 10 K.
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Introduction
The interplay of orbital, lattice and spin degrees of freedom is of fundamental importance in understanding the enormous variety of phenomena and ground states in transition-metal compounds1,2,3. In particular, the effects of short and long-range orbital ordering or of dynamic and static cooperative Jahn-Teller (JT) distortions on the magnetic ground state have been in the focus of condensed-matter physics throughout the research activities on, for example, cuprates and manganites. The respective JT active magnetic ions Cu2+ and Mn3+ usually exhibit a strong JT coupling in octahedral environment and contribute to cooperative JT distortions and orbital ordering far above room temperature, e.g. in KCuF3 and LaMnO34,5,6. Similar electronic configurations are found in the case of compounds containing Fe2+ or Cr3+-ions in a tetrahedral crystal-field2,7,8,9,10, but the electron-lattice coupling is generally weaker and competes with spin-orbit coupling and exchange interactions, leading to strong fluctuations and frustration effects.
FeCr2S4 is a sulfur spinel that has been reported previously to exhibit a complex interplay of orbital correlations and magnetism, including ferrimagnetic ordering of the Cr and Fe sublattices below TC ≈ 170 K11,12 and a transition at TOO = 10 K, which has been assigned to originate from orbital ordering7,12,13,14,15,16,17,18,19. In addition, an anomaly in the low-field magnetization at TM = 60 K revealed a change in the magnetic configuration12,20,21,22,23,24,25, which has recently been attributed to the formation of a non-collinear (possibly helical) spin configuration with an incommensurate modulation involving three different Fe sites as indicated by μSR, Mössbauer and time-resolved magneto-optical Kerr effect measurements26,27,28. The same temperature has also been associated with the onset of short-range orbital order (orbital liquid) and dynamic JT distortions, suggesting a mutual influence of spin configuration and orbital correlations12.
At room temperature FeCr2S4 crystallizes in the spinel structure with space group with eight formula units per unit cell. The Cr3+-ions (3d3, S = 3/2) occupy the octahedral sites and the Fe2+-ions (3d6, S = 2) are at the centre of S2− tetrahedron ions, forming a diamond lattice of two interlacing FCC sublattices29. While the Cr sublattice is dominated by ferromagnetic exchange which is established through the 90° Cr–S–Cr bond, the exchange coupling within the Fe sublattice is rather weak and overruled by a much stronger antiferromagnetic coupling to the Cr-ions, resulting in the ferrimagnetic arrangement. As the Cr3+-ions with a half-filled t2g ground-state configuration do not possess orbital degrees of freedom, the orbital physics in this compound is dominated by the Fe2+-ions. Because of the internal exchange field below TC, the five-fold spin degeneracy of the lower-lying5E states is lifted and the level splits into five orbital doublets. The lowest level is coupled to lattice vibrations, inducing a dynamic JT effect before an eventual formation of a static cooperative JT distortion of the sulfur tetrahedra below T = 10 K29,30. Previous specific heat measurements show a λ-like anomaly at TOO, which was interpreted as evidence for an orbital order at low temperature12. However, an unambiguous signature of a structural JT distortion, predicated by a deviation from cubic symmetry, remains evasive even in high-resolution structural x-ray studies. Thermal expansion measurements have revealed a contraction of the lattice at TOO12.
The influence of an external magnetic field on the magnetization of FeCr2S4 in the orbitally ordered phase was reported recently and it was proposed that there exists a new magnetic phase for fields larger than 5.5 T, which might be related to the restoration of a commensurate collinear spin structure31. Related compounds FeCr2O4 and CoCr2O4 (with orbital degrees of freedom) have been found to be multiferroic32,33 and CoCr2O4 exhibits unconventional properties as a function of applied magnetic field. Therefore, we focus in this study on the influence of external magnetic fields on the structural, magnetic and dielectric properties of FeCr2S4 in the orbitally ordered phase. We identify a decrease of the cubic lattice parameter below TOO and a step-like increase of the magnetic moments of the Cr-and Fe-ions upon application of an external magnetic field. Moreover, our dielectric measurements in magnetic fields provide evidence for the existence of a ferroelectric polarization in FeCr2S4. All investigated quantities show changes in magnetic fields of about 5 T.
Results and discussion
Neutron diffraction
High resolution neutron diffraction patterns were collected on the instrument Echidna, located at the Bragg Institute, ANSTO, at temperatures of T = 4 K, 15 K, 70 K and 100 K. Figure 1(a) presents raw data collected at 4 K, together with the final Rietveld refinement results. Refinements of the diffraction patterns were performed in the high-symmetric cubic spinel structure with the space group (no. 227). The atoms are located at the following Wyckoff positions: Fe at 8a (, , ), Cr at 16d (, , ) and S at 32e (x, x, x). Instrumental parameters were fitted using the diffraction pattern measured at 4 K and fixed for the refinement of the succeeding datasets. Fitted structural parameters of the Rietveld refinements for 4 K and 15 K are listed in Table I. Within the resolution limits of the instrument the sulfur position parameter x did not change between 4 and 15 K, but there is a notable decrease of the cubic lattice parameter between T = 4 K and 15 K as shown in the inset of Fig. 1(c).
Therefore, we further investigated this trend in a detailed neutron diffraction study. Diffraction patterns were collected on the high intensity instrument WOMBAT, located at the Bragg Institute, ANSTO, at temperatures from 4 K to 300 K in 1 K steps, which revealed the transition to ferrimagnetic order below TC ≈ 180 K. The full 4 K to 300 K diffraction dataset was systematically refined to the cubic spinel space group . Initial crystal and magnetic phase parameters were set using the results of the refinement of the high-resolution data. Instrumental characteristics such as peak shape parameters were fitted for the 4 K dataset and fixed for succeeding temperature refinements. Above 200 K the magnetic phase was not included in the refinement. The refined cubic lattice parameter and magnetic moments of the Cr- and Fe-ions are plotted in Fig. 1(c) and 1(d), respectively, which demonstrate the consistency between the temperature dependency of the high-intensity and high-resolution neutron diffraction studies. The insert of Fig. 1(c) reveals a distinct reduction of the cubic lattice parameter below 10 K. This contraction can be interpreted as a microscopic signature of the antiferro-orbital long-range order below TOO = 10 K. In Fig. 1(c) we show that the temperature-dependent trend in the lattice parameter below TC to TM at 60 K is well described by normal anharmonic lattice dynamics and was fit accordingly to V(T) = VO[1 + A/[exp(θ/T) − 1]], where VO represents the cell volume extrapolated to 0 K, θ is an averaged Debye temperature (θ = 481 K in the ferrimagnetic region) and A is a fitting constant. In the transition from paramagnetic to ferrimagnetic order at TC a deviation in the lattice parameter contraction is found to form as a result of magnetostriction. More intriguing is a deviation from the fitted curve for a normal anharmonic solid below 60 K, which indicates enhanced shrinking of the lattice parameter. To our knowledge these deviations in structural characteristics have not been microscopically identified using neutron diffraction prior to this study. However, they are consistent with previous bulk techniques such as thermal expansion measurements12. The behavior below TM ≈ 60 K has previously been associated with short-range orbital fluctuations12 and the emergence of a non-collinear spin configuration26.
The temperature dependency of the magnetic moment of the Fe- and Cr-ions as determined from the refinement of the neutron diffraction data are presented in Fig. 1(d). The magnetic phase symmetry was defined to align the Fe and Cr moments antiparallel along the structural c-direction as our data indicates that the spins are aligned along the cubic crystal axes. No additional Bragg reflections, which would indicate a weak spin canting or incommensurate structure, were detected within the experimental resolution. Simulations of a possible spin canting did indicate that additional transversal magnetic components of no larger than 0.3 μB/Fe2+-ion could exist below 60 K. The obtained values of −3.69 μB and 2.64 μB for the Fe- and Cr-ions at 4 K, respectively, are consistent with values recently determined in a neutron diffraction study18, along with other experimental and theoretical approaches, which are compared in Table II. In particular, density-functional based calculations found reduced spin moments of −3.3 μB and 2.7 μB for both types of ions and an orbital moment of −0.13 μB on the Fe-ions37,38. This is in agreement with our resulting total magnetic moments within experimental error. The orbital contribution of the Fe-ions is argued to originate from spin-orbit coupling38, which is in agreement with the single-ion picture, where the second-order contribution of spin-orbit coupling yields an effective g-factor of g = 2.139. The successful refinement of the FeCr2S4 magnetic structure indicated that the spin-only moments are reduced from expected values of −4.2 μB for Fe2+ with S = 2 and g = 2.1 and 3.0 μB for Cr3+ with spin S = 3/2 and g = 2. Moreover, recent reports have indicated modifications to the bulk magnetic properties of FeCr2S4 under large applied magnetic fields in this temperature range31,40.
Neutron diffraction was performed on FeCr2S4 under external applied magnetic fields of up to 7.5 T in order to investigate a potential link between orbital order, the magnetic and crystal structures and external fields. In particular, deviations in the magnetic and crystal structure were studied by performing Rietveld refinement of the lattice and magnetic moment parameters of the Fe2+ and Cr3+-ions. Neutron diffraction patterns were collected on the instrument Wombat at ANSTO under applied magnetic fields from 3 T up to 7.5 T in 0.5 T steps at temperatures from 5 K up to 15 K in 1 K steps. For the Rietveld refinements, the collected diffraction patterns were treated using the cubic spinel structure and collinear antiparallel magnetic structure as determined previously, since there was no evidence for additional Bragg peaks within the experimental resolution. Crystal and magnetic structural parameters were initially set based upon the results of the zero-field refinement results (see Table I). Under an initial applied field of 0.5 T, the Fe- and Cr-ion spins structure of cubic FeCr2S4 preferentially rotates to align along the crystal axis in the applied magnetic field direction. Additional parameters to account for this preferential orientation of the magnetic phase were implemented in the refinement, resulting in a significant improvement to the fitting residuals.
The obtained lattice parameter and magnetic moments are presented in Fig. 2. In Fig. 2(a) the reduction of the cubic lattice parameter below TOO observed in zero-field remains visible under applied magnetic fields up to 7.5 T. This indicates that the phase below TOO remains stable with respect to even relatively large external magnetic fields. A clear increase in the obtained magnetic moment of the Fe2+ and Cr3+-ions occurs at around 4.5 T (Fig. 2b,c,d), with spin-only values of −4.2 μB and 3.0 μB approached for fields above 5.5 T, respectively.
The reduced magnetic moments observed in neutron diffraction in zero-field can be explained due to the existence of a transverse quasi-paramagnetic component of the magnetic moment of the Fe2+-ions. According to previous publications, they are a consequence of the orbital moment of the Fe-ions which causes an magnetocrystalline anisotropy with an estimated magnitude of about 2–4 T in the magnetically ordered regime T < TC28,37,38. A possible scenario to understand the observed increase is that these transverse components are suppressed in the external magnetic field and the magnetic moments reach the full spin-only values of the longitudinal magnetization. The strength of the necessary magnetic field is in good agreement with reports of a change in slope of the magnetization as a function of field31,40 and with the order of magnitude of the field necessary to overcome the magnetocrystalline anisotropy in FeCr2S428. Therefore, we believe that for fields larger than 5.5 T FeCr2S4 becomes an isotropic ferrimagnet. At the same magnetic field strength the magnetostriction and the dielectric properties also show distinct changes, as discussed in the following.
Thermal expansion, magnetostriction and specific heat
The temperature dependence of the thermal expansion (L(T) − L200K)/L200K of the sample's thickness L in the direction of the applied magnetic fields of a dense polycrystalline sample obtained by spark-plasma sintering are shown in Fig. 3(a) together with zero-field data reported in Ref. 12. In the paramagnetic phase at 200 K we do not expect any significant magneto-strictive effects enabling us to compare directly the effect of the external magnetic field, by normalizing the data to the thickness L200K of the sample at 200 K. The temperature dependence in zero field clearly shows a contraction of the sample upon entering the state below 10 K12, which is in agreement with the temperature evolution of the lattice parameter in Fig. 1(c).
The effect of the external magnetic field above 100 K is small, but a clear broadening of the anomaly at the ferrimagnetic transition is found in the linear thermal-expansion coefficient αL = 1/L(∂L/∂T) for the direction parallel to the applied magnetic field (Fig. 3(b)). In the temperature range 60 ≤ T ≤ 130 K only slight deviations from the zero-field curve can be detected. However, below about 60 K the sample contracts much stronger when a magnetic field is applied. This temperature coincides with the temperature TM where a transition from a collinear to a non-collinear spin configuration with three different Fe sites has been reported by μSR and where orbital fluctuations are assumed to set in12,26,27. The relative change of the thermal expansion upon entering the ground state below 10 K is similar to the zero-field data, but under applied fields of 6 T and 12 T the sample expands again towards lowest temperatures. This is clearly seen in the negative thermal expansion coefficient for the transition in magnetic fields. The temperatures of the minima in the thermal expansion in magnetic fields are used as a measure of the orbital-ordering transition temperatures.
The relative magnetostriction effect of the sample (L(H) − LH = 0)/LH = 0) is shown in Fig. 3(c) for selected temperatures, which are also indicated by arrows in the inset of Fig. 3(a). The values at 12 T are compared with the values (large solid symbols in Fig. 3(c)) obtained by subtracting the corresponding temperature dependencies in Fig. 3(a). The different data sets agree well. The deviations at lower temperatures might indicate small variations in temperature during the different measurements. At high temperatures the field effects are small and the almost field independent zero-magnetostriction curve at 70 K indicates a sign change as expected from the temperature dependence of the thermal expansion. Accordingly, the largest contraction is observed at 12 K, just above the orbital ordering transition. At both 12 K and 25 K the lattice contracts strongest in field from zero to about 2 T, undergoes a very broad shallow minimum and tends to saturate up to the highest measured fields. In the orbitally ordered state a broad but clear minimum develops at around 3–4 T, signaling the change from a contraction to an expansion of the sample in higher magnetic fields. The external fields Bc1 and Bc2 associated with this change are estimated by the values where the magnetostriction curve increases visibly from the minimal value (indicated as a constant solid line) and by the inflection points, respectively.
From the neutron scattering results in magnetic field, it is clear that the volume contraction of the lattice below TOO is still present in magnetic fields up to 7.5 T. The strong effects seen in the macroscopic thermal expansion measurement must therefore be related to the existence of magnetic domains in the investigated sample. In fact, the largest changes occur in fields smaller than 2 T (see Fig. 3)(c) at temperatures below TM = 60 K, where strong domain formation has been reported22 in agreement with the observation of small hysteretic effects. Within the magnetic field range of our study, the contraction of the sample seems to saturate above 3–4 T and above TOO, indicating that the magnetic domain structure is stabilized. In the orbitally ordered state, however, an expansion of the sample sets in between Bc1 and Bc2. As mentioned above this field range coincides with the increase of the magnetic moments of the Fe- and Cr-ions and reflects the order of magnitude of the magnetocrystalline anisotropy.
In Fig. 3(d) we compare the temperature dependence of the specific heat in the representation CP/T vs. T in zero and 9 T fields. While the sharp anomaly at the ferrimagnetic transition at 165 K in zero field is strongly broadened at 9 T, the changes of the λ-like anomaly around 10 K at the orbital-ordering transition (shown in the inset for several external magnetic fields) exhibits only a small shift and a transfer of associated entropy to higher temperatures with increasing magnetic field. This indicates that the orbital configuration of the ground state is rather stable with respect to the applied magnetic field, but critical fluctuations are favored to occur at higher temperatures already. A shift of the anomaly and an entropy transfer at 14 T has been reported40, which is similar to the one we observe at 9 T. The temperatures of the orbital-ordering transition at 9.2, 9.5, 9.9 and 10.3 K for 0, 1, 6 and 9 T, respectively, were evaluated from the CP/T dependencies in terms of the temperatures where the data starts to deviate from a linear fit at temperatures above the maximum (see inset of Fig. 3(d)). The ferrimagnetic transition temperature in zero-field is determined by the same procedure as TC = 165 K. At 9 T the transition temperature has been evaluated as the intersection point of two linear extrapolations below and above the broad maximum (see Fig. 3(d)).
Dielectric spectroscopy
In this section we present detailed measurements of the dielectric constant as a function of temperature and external magnetic fields specifically focusing on the occurrence of magnetoelectric effects. Temperature and frequency dependent of the dielectric loss has been reported earlier. In single crystals where the transition at 10 K was suppressed evidence for a gradual freezing of the orbital degrees of freedom has been observed19. However, in these crystals the conductivity was significantly enhanced compared to the samples investigated here and Maxwell-Wagner like relaxations extended down to the lowest temperatures41. Measurements of the dielectric constant as a function of temperature and magnetic field had not been reported. Recently the occurrence of multiferroicity in the orbitally ordered phase of FeCr2S4 has been discussed42. Figure 4(a) shows the temperature dependence of the dielectric constant ε′ of FeCr2S4 around the orbital ordering transition at TOO ≈ 10 K for frequencies between 300 Hz and 10 kHz and external magnetic fields up to 1 T. In these measurements the magnetic field was oriented parallel to the electric field, H || E. For all frequencies and magnetic fields the dielectric constant decreases on decreasing temperatures reaching constant low-temperature values below 6 K in the orbitally ordered state.
The orbital ordering transition in the 10 kHz-curve is indicated by a kink in the dielectric constant and is present for all applied magnetic fields. At lower frequencies the transition is masked by the increase of the dielectric constant towards higher temperatures due to an extrinsic Maxwell-Wagner relaxation41. The strong increase of the dielectric constant in external magnetic fields of 1 T at low temperatures indicates a magnetic-field induced effect of the polarization and will discussed further in the following.
In Fig. 4(b) we plot the change of the dielectric constant induced by an applied magnetic field for the configurations H || E and H ⊥ E. The behavior is clearly nonlinear for both configurations. Notably, a positive contribution occurs for H || E and a smaller negative one for H ⊥ E. In both configurations we observe weak hysteretical behavior in low magnetic fields (not shown) and a change of slope in the applied magnetic field range 4.5 T < H < 5.5 T (hatched area in Fig. 4(b)) were observed. The latter effect is also documented in the neutron scattering and magnetostriction results discussed above. For H || E we plot together with the magnetization M(H) of the sample in Fig. 4(c). Both curves can be scaled to fall on top of each other indicating , which even holds in the field range 4.5 T < H < 5.5 T. This relation is confirmed in Fig. 4(c), where is plotted directly vs. M(H) and reveals a linear correlation between the two quantities with a slope of 4.1 (f.u./μB).
To understand this magnetic-field dependence we assume that the polarization of the sample as a function of electric and magnetic field may be written as
where P0(E, H) is a possible spontaneous polarization, which may depend on the applied fields, χe denotes the electric susceptibility tensor and α the tensor of the linear magnetoelectric effect. Higher order terms in E and H are neglected. As the polarization exhibits a strongly nonlinear dependence on the applied field, we also neglect the linear magnetoelectric effect in the following.
In the dielectric measurement the dielectric tensor is evaluated by assuming
with P = P0(E, H) + ε0χeE. The presence of a static electric polarization P0(E, H) may then result in an effectively magnetic-field dependent . Here, investigating a polycrystalline sample and E = (0, 0, Ez) = Ezez along the z-direction in the laboratory system we can distinguish two cases for the dielectric constant according to the relative orientation of the applied magnetic and electric fields:
The experiment shows that while , which originates from a change of the polarization component along the z-axis in the presence of the applied magnetic field. Applying the magnetic field perpendicular to the electric field obviously reduces the projection of the total polarization on the z-axis and leads to .
Given the linear relation between and the magnetization M(H) we conclude that within our assumptions the z component P0(Ez, Hz) · ez of the polarization and the corresponding ferroelectric domains undergo the same changes as the magnetic domains and that ferroelectric and ferrimagnetic domains are linked to each other in FeCr2S4.
A similar situation has recently been reported in single crystals of the multiferroic spinel CoCr2O432,43, which is comparable to FeCr2S4: it is isostructural at room temperature, becomes a collinear ferrimagnet below about 95 K and ferroelectric below 27 K as a result of a conical-spiral magnetic ordering32,43. At the latter phase transition the dielectric constant in CoCr2O4 reportedly exhibits a small cusp similar to the effect shown in Fig. 4(a). For CoCr2O4 a spin-driven origin has been proposed as the origin of multiferroicity.
Although the observed field dependence of the dielectric constant is not a direct proof of the existence of a static polarization component and multiferroicity, we believe that in FeCr2S4 a similar mechanism might be active. In our opinion, the clearly linear correlation between shown in Fig. 4(c) strongly points towards a multiferroic ground state of FeCr2S4. However, the actual spin arrangement of FeCr2S4 below 50 K remains unsolved. Assuming a scenario where ferroelectric and ferrimagnetic domains are clamped, the field dependence of in Fig. 4(c) in fields below 1 T can be understood in terms of ferroelectric domain reorientation and alignment effects, which are induced by the alignment of magnetic domains. The change of slope at 4.5 T < H < 5.5 T is then related to the changes in the magnetization and the increase of the magnetic moments of the Fe- and Cr-ions assigned to the overcoming of the magnetocrystalline anisotropy.
Summary and conclusions
Using neutron diffraction we observed a reduction of the cubic lattice parameter below TOO ≈ 10 K in agreement with bulk measurements in thermal expansion. This transition was previously attributed to an onset of orbital order12 and is not altered under an external magnetic field as demonstrated by our neutron diffraction and specific heat measurements. In the field range 4.5 T < H < 5.5 T an increase of the magnetic moments of the Fe- and Cr-ions appears. The bulk magnetization accordingly exhibits a change of slope and the magnetostriction causes an expansion of the sample along the direction of the applied field. These changes are attributed to the magnetocrystalline anisotropy, which is overruled by the external magnetic field, inducing an isotropic ferrimagnetic state for fields larger than 5.5 T. In this isotropic regime, the magnetic moments of the Fe and Cr reach the expected spin-only values, suggesting that transverse components of the magnetization are suppressed together with the magnetocrystalline anisotropy.
The dielectric measurements revealed a strong dependence on the applied magnetic fields. In case of parallel applied electric and magnetic fields, a linear correlation between the dielectric constant and the magnetization measured in magnetic field is established. We interpret this behavior as an indication for the existence of a ferroelectric polarization in FeCr2S4, where ferroelectric and magnetic domains are strongly coupled to each other. To corroborate such an interpretation we suggest that future studies may be directed to search for structural features of a polar symmetry group in FeCr2S4.
Based on these results, we show a modified H − T phase diagram of FeCr2S4 in Fig. 5. In the orbitally ordered state below about 10 K, we assign the observed features to a ferroelectric ground state and, hence, regarded FeCr2S4 as a multiferroic material like the related spinel CoCr2O432,43. Most multiferroic materials are antiferromagnetic and the spin order cannot be addressed directly by an external magnetic field. This problem would be largely overcome by the predominantly ferrimagnetic structure of FeCr2S4 and would hence open new routes for basic research and applications in this potentially new multiferroic material.
The changes in the field range 4.5 T < H < 5.5 T and for the lowest temperatures are assigned to a transition into an isotropic ferrimagnetic state. The corresponding necessary magnetic fields increase when approaching the orbital ordering temperature from below and reach up to about 10 T. Due to the increasing conductivity with temperature, no such clear anomalies were observed in the orbital liquid regime above 10 K, but it can not be excluded that ferroelectric domains, which are only weakly clamped to the magnetic domains, are already present in the orbital liquid regime.
Methods
Polycrystalline samples of FeCr2S4 for neutron experiments were prepared by solid-state reaction using high-purity elements. Post growth annealing under a chalcogen atmosphere was performed to achieve a pure stoichiometric ratio, which has been shown previously to exhibit the strongest low temperature anomaly12. For preparation of dense samples for thermal expansion and specific heat measurement, we used a spark-plasma-sintering (SPS) technique as described in Ref. 12. While both samples exhibit the orbital ordering transition at about 10 K, the sample obtained by SPS showed a reduced ferrimagnetic transition temperature of 165 K in comparison to the one used for the neutron diffraction study with TC = 180 K. Thermal-expansion, magnetostriction and dielectric experiments were carried out in a home-built setup using a capacitance bridge (AH 2700 Hagerling) for temperatures from 1.5–300 K and in external magnetic fields up to 14 T. The sample had the shape of a platelet and the expansion was measured along the direction of the applied magnetic field, which is perpendicular to the platelet. Dielectric measurements were perfomed using silver-paint contacts applied on both sides of the platelike sample, the magnetic field was applied perpendicular and parallel to the electric field. The heat capacity was measured in a physical properties measurements system (PPMS, Quantum Design) for temperatures between 1.8 K and room temperature and in external magnetic fields up to 9 T.
High resolution powder neutron diffraction measurements were performed using the instrument Echidna, located at the Bragg Institute, ANSTO, Sydney, Australia. Echidna is equipped with 128 3He linear position sensitive detectors that are scanned in position to produce high resolution diffraction patterns with an angular step of 0.05°. A Ge monochromator was aligned on the (331) reflection with a take-off angle of 140° to select a wavelength of 2.4395 Å with a calculated accessible Q-range of 0.2–5.1 Å−1. Collimation ensured a minimum FWHM resolution of ~0.4°. To achieve a good signal to noise ratio, each diffraction pattern was collected for 6 hours. The symmetry of the FeCr2S4 crystal and magnetic structures were characterized by performing a least-squares Rietveld refinement of the powder neutron diffraction data, using the fullprof software suite44.
The high-intensity powder neutron diffractometer Wombat, located at the Bragg Institute, was used to conduct temperature and applied magnetic field dependency studies of the magnetic and crystal structures of FeCr2S4. Magnetic fields up to 7.5 T were applied using a vertical closed-cycle cryomagnet (Cryogenic Ltd.). Wombat uses a monolithic position-sensitive 3He detector, enabling fast collection times with little penalty to resolution. A vertically focused Ge monochromator was set to align on the (113) reflection, with a 90° take-off angle, giving an incident wavelength of 2.41 Å and an accessible Q-range of 0.5–4.9 Å−1. No collimation was used to maximize the count rate, resulting in a required 10 minute collection time per scan.
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Acknowledgements
We thank K.-H. Höck, I. Kezsmarki, H.-A. Krug von Nidda, B. Lake, M. Schmidt and Z. Wang for fruitful discussions and A. Schmidt for technical assistance. We acknowledge partial support by the Deutsche Forschungsgemeinschaft via TRR 80 (Augsburg-Munich). M.W. and S.K. acknowledge the support by the Federal Ministry of Education and Research via project 03EK3015. J.B. and C.U. acknowledge the support of the Australian Institute of Nuclear Science and Engineering (AINSE) and the support of the Australian Research Council through the Discovery Projects funding scheme (project DP110105346).
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J.B., C.U., A.G., M.R., A.J.S. and M.A. participated in the neutron diffraction experiment and performed the data analysis. V.T., D.V.Q. and J.R.G. prepared and characterized the samples. A.G., F.S., V.T. and J.D. conducted and analyzed specific heat, thermal expansion and magnetization measurements. M.W. and S.K. performed and analyzed the dielectric measurements. All authors contributed to the interpretation of the data and to the writing of the manuscript. C.U., A.L. and J.D. conceived and supervised the project.
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Bertinshaw, J., Ulrich, C., Günther, A. et al. FeCr2S4 in magnetic fields: possible evidence for a multiferroic ground state. Sci Rep 4, 6079 (2014). https://doi.org/10.1038/srep06079
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DOI: https://doi.org/10.1038/srep06079
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