Abstract
The ternary RMn2Ge2 (R = rare earth) intermetallic compounds have attracted great attention due to their interesting magnetic behaviors and magnetotransport responses. Here, we reported our observation of anisotropic magnetic property, magnetostriction, and magnetocaloric effect (MCE) in TbMn2Ge2 single crystal. Below the transition temperature of Tb magnetic sublattices (\(T_{{\text{C}}}^{{{\text{Tb}}}}\) ~ 95 K), strong Ising-like magnetocrystalline anisotropy is observed with an out-of-plane ferromagnetic moments 5.98 μB/f.u. along the easy c axis, which is two orders of magnitude larger than that of field along a axis. Above \(T_{{\text{C}}}^{{{\text{Tb}}}}\), a field-induced metamagnetic transition is observed from the spin-flip of Mn sublattices. During this transition, remarkable magnetostriction effect is observed, indicating of strong spin–lattice coupling. The responses of Tb and Mn sublattices to the magnetic field generate a giant magnetic entropy change (\(- \Delta S_{M}\)) and large values of relative cooling power (RCP) and temperature-averaged entropy change (TEC). The calculated maximum magnetic entropy change (\(- \Delta S_{M}^{\max }\)), RCP, and TEC(10) with magnetic field change of 7 T along c axis reach 24.02 J kg−1 K−1, 378.4 J kg−1, and 21.39 J kg−1 K−1 near \(T_{{\text{C}}}^{{{\text{Tb}}}}\), which is the largest among RMn2Ge2 families. More importantly, this giant MCE shows plateau behavior with wide window temperatures from 93 to 108 K, making it be an attractive candidate for magnetic refrigeration applications.
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Introduction
Magnetocaloric effect (MCE) is the phenomenon which converts magnetic energy into thermal energy by changing the applied magnetic field1,2,3,4,5,6. Based on the MCE, magnetic refrigeration technology is proposed, and it has attracted great attention due to the high energy efficiency and environmental friendliness. The MCE can be quantified by adiabatic temperature change or isothermal magnetic entropy change (\(- \Delta S_{M}\)) for a certain magnetic field variation1,2,3,4,5,6. Up to date, numerous magnetic refrigeration materials with giant \(- \Delta S_{M}\) accompanied by first order phase transition have been reported5,6. Although the MCE is intrinsic for all magnetic materials, only some of them which have strong MCE and small hysteresis loss are desirable for practical application1. In addition, giant reversible MCE only appears in a narrow temperature range for most of the existing magnetic refrigeration materials. Therefore, it is important to search for materials that exhibit giant MCE not only with small hysteresis loss but also with a wide temperature range.
The ternary intermetallic compounds with the formula of RT2X2 (R = rare earth, T = transition metal, and X = Si, Ge) have been extensively studied due to superconductivity, magnetic ordering, and heavy-fermion properties7. During the last few years, the compounds have also been found to possess giant MCE with small hysteresis loos near the magnetic ordering temperature8,9,10,11,12. They crystalize in ThCr2Si2-type tetragonal structure with space group I4/mmm7. As shown in Fig. 1a, the structure consists of R, X, and T layers which alternately stack along c axis, and the R, T, and X atoms occupy 2a, 4d, and 4e positions, respectively7. In this series, special attention has been devoted to RMn2X2 compounds because of the magnetic Mn sublattices11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38. They present a vast variety of magnetic structures and magnetic phase transitions, and the magnetic state can be selected by controlling the interlay and intralayer distance between the magnetic atoms21,22,23. Very recently, the RMn2Ge2 compounds have triggered renewed interests due to the nontrivial transport behaviors, such as the spontaneous skyrmions and the giant topological Hall effect39,40,41,42,43,44,45. From the results of magnetization measurement in single crystal samples, significant change in magnetization is obtained during the magnetic transition. For example, a spin reorientation of Mn moments is observed at 215 K for NdMn2Ge240, and a rapid upturn of magnetic susceptibility from paramagnetic (PM) to ferromagnetic (FM) transition along c axis is obtained at 325 K39. These features suggest that the giant MCE may be available near the magnetic transition region. Additionally, a magnetic field-induced metamagnetic transition at certain temperature has been detected in Tb1-xYxMn2Ge233. As the direction of the magnetic moment and the symmetry of the spin texture in metamagnetic transition can be easily changed by external magnetic field, sufficient low field MCE can be achieved12. To clarify the intrinsic magnetic behavior and the possible application in magnetic refrigeration, it is important to investigate the magnetic properties on single crystal samples. In this work, we present a systematic study on the anisotropy magnetic property, magnetostriction, and the MCE in TbMn2Ge2 single crystal. Large magnetocrystalline anisotropy below the transition temperature of Tb magnetic sublattices (\(T_{{\text{C}}}^{{{\text{Tb}}}}\) ~ 95 K) and a field-induced metamagnetic transition above \(T_{{\text{C}}}^{{{\text{Tb}}}}\) are observed, and remarkable magnetostriction is accompanied by these magnetic transitions. Strikingly, giant MCE with plateau behavior in a wide window temperature near \(T_{{\text{C}}}^{{{\text{Tb}}}}\) is obtained for magnetic field along c axis. Moreover, a magnetic phase diagram is constructed based on the magnetic results.
Experimental details
The TbMn2Ge2 single crystal was grown using an Indium flux method39,42. The starting materials with a molar ratio of Tb:Mn:Ge:In = 1:2:2:20 were put into an alumina crucible and sealed in a quartz tube under high vacuum. During the growth process, the tube was firstly heated up to 1373 K and kept at this temperature for 12 h. Then, it was slowly cooled to 973 K with a rate of 2 K/h. Finally, to separate the single crystal from the Indium flux, the tube was taken out from the furnace at 973 K, and the Indium flux was decanted by centrifugation.
The crystal structure was checked using an x-ray diffractometer (XRD, SmartLab, Rigaku) with Cu-Kα radiation. The crystal orientation was checked using a Rigaku XtaLab-mini-II diffractometer with Mo-Kα radiation. The elemental analysis was performed on a scanning electron microscope (SEM, JSM-IT500HR, JEOL) with an energy dispersive spectrometer (EDS). The magnetic measurements were carried out using a vibrating sample magnetometer (VSM) on a physical property measurement system (PPMS, Quantum Design). The isothermal magnetization curves for calculating the \(- \Delta S_{M}\) were measured in discrete steps from 90 to 115 K with temperature interval of 0.5 K, and the sample was heated to the PM temperature region and demagnetized in oscillatory mode before each measurement46. To eliminate the influence of demagnetizing field, the demagnetization correction was performed, and the effective field was estimated by subtracting the demagnetization field from the external field (μ0Hext) using the equation \(\mu_{0} H = \mu_{0} (H_{{{\text{ext}}}} - N_{{\text{d}}} M)\), where Nd is the demagnetization factor47. The Nd is calculated to be 0.1085 and 0.6629 along a and c axes, respectively. All the results were discussed based on the data after the demagnetization correction. The magnetostriction was measured using a strain gauge (KFLB, Kyowa) based on Wheatstone bridge principle, and the imbalance of the bridge was measured using a lock-in amplifier (SR830, Stanford Research Systems).
Results and discussion
The room-temperature powder XRD pattern of TbMn2Ge2 is shown in Fig. 1b. The diffraction peaks can be well fitted with the tetragonal structure7, which confirms high purity of the prepared sample. The stoichiometry ratio of Tb, Mn, and Ge is estimated to be 20.82:39.47:39.71 from the EDS results, indicating the spatially uniform stoichiometry of TbMn2Ge2 single crystal (see Fig. S1 in supplementary material for details). Figure 1c shows the representative photograph of TbMn2Ge2 single crystal on the grid paper. The crystal has a rectangular shape in a dimension of 1.88 × 0.92 × 0.29 mm3. Room-temperature XRD experiment was performed on the plate-like single sample. As shown in Fig. 1d, the XRD patterns for the front of the plate can be indexed by the indices of (00 l) (l = 2, 4, 6, 8) plane, and the patterns for the side are indexed by the indices of (h00) (h = 2) plane (see Fig. S2 in supplementary material for details). The results indicate that the in-plane and out-of-plane directions are parallel and perpendicular to the ab plane. The directions of a and b axes are indicated by the arrows in Fig. 1c, and the normal direction of the plate is parallel to c axis.
To explore the magnetic properties, temperature dependence of zero-field-cooled (ZFC) and field-cooled (FC) magnetization with μ0H = 0.1 T along a and c axes is measured in the temperature range from 3 to 400 K, and the results are shown in Fig. 2a,b, respectively. With decreasing temperature, the magnetic behavior is quite different for magnetic field along a and c axes, exhibiting large magnetocrystalline anisotropy. For μ0H//a in Fig. 2a, there are two remarkable transitions, which include a gradual increase in magnetization at 296 K and a sudden decrease at 95 K. While for μ0H//c in Fig. 2b, an abrupt increase in magnetism at 95 K is observed. Based on the neutron diffraction experiment, L. Morellon, et. al. have demonstrated that the moments of Mn atoms are FM ordering along c axis and the Tb moments are also ordered ferromagnetically in the same direction but antiferromagnetically to the Mn sublattices, yielding a collinear ferrimagnetic (Ferri) spin structure along c axis below \(T_{{\text{C}}}^{{{\text{Tb}}}}\)19,20,21. Our results agree well with the neutron diffraction data, but a slightly lower \(T_{{\text{C}}}^{{{\text{Tb}}}}\) ~ 95 K is found. The insets of Fig. 2a,b show the FC curves measured with various magnetic fields near \(T_{{\text{C}}}^{{{\text{Tb}}}}\). With the increase of magnetic field, the transition temperature is driven to higher temperature for μ0H//c, while it remains unchanged for μ0H//a. For the transition at 296 K along a axis, although there is no change in the spin configuration between 200 and 400 K according to the neutron diffraction experiments, similar behavior is observed in Pr1-xTbxMn2Ge219. It is reported that an AFil-type spin structure is formed below Néel temperature (\(T_{{\text{N}}}^{{{\text{inter}}}}\)), and the moments of Mn are FM ordering within the ab layers but antiferromagnetic (AFM) coupling along c axis at \(T_{{\text{C}}}^{{{\text{Tb}}}}\) < T < \(T_{{\text{N}}}^{{{\text{inter}}}}\)21. The FM component of Mn moments in the ab layers may be response for the FM-like transition at 296 K48.
Figure 2c,d show the magnetic field dependence of magnetization in TbMn2Ge2 single crystal with μ0H//a and μ0H//c, respectively. The magnetization increases almost linearly with increasing the magnetic field along a axis, and the isothermal magnetization curves show negligible hysteresis. The hysteresis loops along c axis exhibit FM nature for T < 100 K, and typical hysteresis is observed at 3 and 10 K. It is reported that the magnetic phase is not changed below 19,21. However, we note that the ZFC and FC curves deviate from each other below ~ 20 K (Fig. 2b), and similar phenomenon is observed in previous works19,30,36, suggesting the competition between different magnetic properties. J. Leciejewicz et al. have found that the Tb magnetic sublattice transforms into an AFM one below 26 K32. Additionally, it is worth noting that the similar system TbMn2Si2 exhibits a canted Ferri structure in which the Tb moments lie along the c axis, and the Mn moments are parallel with each other in their own layer and are canted between the Mn sublayers11. The possible changes in magnetic structure may be response for the large coercive field for the data measured at 3 and 10 K in Fig. 2d. The saturation magnetization reaches 5.98 μB/f.u., which is slightly larger than the previous reported value (5.53 μB/f.u.)20,21. At 100 K, the hysteresis loop is linear with the increase of magnetic field at first, and then the magnetic moment is fully polarized at a critical field (μ0HC) of 2.4 T, indicating field-induced metamagnetic transition. Due to that the spin of Tb atoms is disordered above \(T_{{\text{C}}}^{{{\text{Tb}}}}\), the metamagnetic transition should result from the spin-flip of Mn. Before the metamagnetic transition, Mn magnetic moments are AFM ordering along c axis19,21. When the magnetic field is larger than the μ0HC, the FM ordering of Mn moments is formed. At T ≥ 150 K, linear hysteresis loops are observed due to the AFM interaction of Mn20.
To investigate the possible coupling between the magnetic ordering and the structural parameter, the strain change is measured around the magnetic transition region. As shown in Fig. 2e, a sharp step in the relative length change (ΔL/L) is observed along a axis at \(T_{{\text{C}}}^{{{\text{Tb}}}}\). When the field is applied along the easy magnetization c axis, the step moves to higher temperature, and it coincides with the magnetic transition in the inset of Fig. 2b. Based on the Rietveld analysis of neutron diffraction spectra21, it is found that a variation of the Mn magnetic moment, ΔμMn/μMn ≈16%, takes place at \(T_{{\text{C}}}^{{{\text{Tb}}}}\). This transition causes a dramatic jump in a cell parameter, Δa/a ≈ 0.15%, and no anomaly is found in c cell parameter. As we know, the spin alignment of adjacent Mn layers is antiparallel along c axis when \(T_{{\text{C}}}^{{{\text{Tb}}}}\) < T < \(T_{{\text{N}}}^{{{\text{inter}}}}\), and it becomes parallel along c axis below \(T_{{\text{C}}}^{{{\text{Tb}}}}\). It means that the value of a cell parameter is correlated with the spin configuration of Mn. When the magnetic field is applied along c axis, the metamagnetic transition results in the change of Mn spin configuration. This process would induce the anomaly in a cell parameter. Our results agree well with the data in polycrystalline TbMn2Ge221,23. The field dependence of ΔL/L along a axis with μ0H//c is shown in Fig. 2f. It is obvious that a visible change of ΔL/L is observed at a critical field (\(\mu_{0} H^{\prime}_{{\text{C}}}\)), and the \(\mu_{0} H^{\prime}_{{\text{C}}}\) increases with increasing temperature, suggesting remarkable magnetostriction effect. When the magnetic field is applied along a axis, the field-induced anomalies are unavailable (see Fig. S3 in supplementary material for details). The strong response of the lattice to the external magnetic field indicates an unusually large coupling of the Mn magnetic moments to the lattice.
As significant changes in magnetization are obtained near the magnetic transition region in TbMn2Ge2 single crystal, giant MCE is expected, especially for μ0H//c axis. It is well known that giant MCE have a strong correlation with the first order magnetic phase transition5, so it is necessary to understand the nature of the magnetic transition in TbMn2Ge2 single crystal. Figure 3a,b show the isothermal initial magnetization curves with the magnetic field along a and c axes from 90 to 115 K with an interval temperature of 0.5 K. For μ0H//a, a continuous increase in the magnetization is observed at each temperature, and the magnetization increases slightly with the increase of temperature (Fig. 3a). While for μ0H//c, the magnetization gets saturated below 0.5 T magnetic field at 90 K (Fig. 3b). When the temperature reaches 95 K, the metamagnetic transition emerges. At lower temperature, the AFM anisotropy is weak and only a small magnetic field is required to fully polarize the spins along c axis. The μ0HC of the metamagnetic transition gradually increases with the increase of temperature. According to Banerjee criterion, the magnetic transition belongs to second order if all the μ0H/M vs M2 curves (also named as Arrott plot) have positive slope. On the other hand, if some of the μ0H/M vs M2 curves show negative slope at some points, the magnetic transition is of the first order49. The Arrott plot for μ0H//a and μ0H//c are shown in Fig. 3c,d, respectively. Clearly, negative slope can be observed in the Arrott plot in Fig. 3d, indicating the occurrence of first order magnetic transition.
Based on the classical thermodynamical and the Maxwell thermodynamic relations, the \(- \Delta S_{M}\) is given by4:
where \([\partial S(T,H)/\partial H]_{T} = [\partial M(T,H)/\partial T]_{H}\) is based on the Maxwell relation. For magnetization measured at small temperature and field intervals, Eq. (1) can be rewritten as:
The temperature dependence of the calculated \(- \Delta S_{M}\) using Eq. (2) with various magnetic field changes (Δμ0H) along a and c axes are shown in Fig. 4a,b, respectively. For μ0H//a, an inverse MCE with maximum magnetic entropy change (\(- \Delta S_{M}^{\max }\)) of − 1.64 J kg−1 K−1 is obtained near \(T_{{\text{C}}}^{{{\text{Tb}}}}\), and the inverse MCE could be attributed to the magnetic transition of Tb sublattices from disorder to order along c axis, which induces a slight increase of magnetization along a axis. In contrast, a normal MCE is obtained for the magnetic field along c axis, and the \(- \Delta S_{M}^{\max }\) is evaluated to be 24.02 J kg−1 K−1 with Δμ0H = 7 T at \(T_{{\text{C}}}^{{{\text{Tb}}}}\), exhibiting giant MCE. The other significant feature in Fig. 4b is that a plateau behavior for the giant MCE is obtained with larger Δμ0H, resulting in a wide temperature range with large \(- \Delta S_{M}\). The peak width determined from the difference between the extreme values in the \({\text{d}}\Delta S_{M} {\text{/dT}}\) vs T curves is proportional to Δμ0H, and it reaches up to 16 K with Δμ0H = 7 T. For Δμ0H = 5 T, the \(- \Delta S_{M}^{\max }\) is evaluated to be 23.23 J kg−1 K−1. As shown in Fig. 4c, this value is much larger than that in TbMn2Ge2 polycrystal sample33 and other RMn2Ge2 compounds14,15,16,17,18. Meanwhile, it is comparable with the series of RT2X2 compounds with giant MCE8,9,10,11,12. Moreover, the temperature of \(- \Delta S_{M}^{\max }\) appears at 95 K for present sample, which is much higher than the values in above-mentioned compounds.
Figure 4d shows the Δμ0H dependence of \(- \Delta S_{M}^{\max }\) for μ0H//c. The value of \(- \Delta S_{M}^{\max }\) increases rapidly with increasing Δμ0H from 0 to 1 T, and then it gets saturate gradually. For the relatively small value of Δμ0H, the \(- \Delta S_{M}^{\max }\) reaches up to 20.69 J kg−1 K−1 (Δμ0H = 1 T), suggesting giant low field MCE. Except for the \(- \Delta S_{M}\) parameter, the relative cooling power (RCP) is also usually used to characterize the potential MCE of materials, which indicates the amount of heat transfer between the cold and hot reservoirs in an ideal refrigeration cycle6. It is given by:
where FWHM means the full width at half maximum in \(- \Delta S_{M}\) curve. The variation of RCP is consistent with that of \(- \Delta S_{M}^{\max }\). As shown in the inset of Fig. 4d, for Δμ0H larger than 1 T, both of \(- \Delta S_{M}^{\max }\) and RCP parameters can be well fitted using the power law relations: \(- \Delta S_{M}^{\max } = a + b(\mu_{0} H)^{m}\) and \({\text{RCP}} = c + d(\mu_{0} H)^{n}\), and the fitting yields the values of a, b, m, c, d, and n to be 20.52, 0.132, 0.770, − 61.14, 20.564, and 0.722. For TbMn2Ge2 single crystal, the RCP reaches a maximum value of 378.4 J kg−1 with Δμ0H = 7 T along c axis, which is of the same order of magnitude as other high-performing magnetic refrigeration materials11,12. Considering that the RCP tends to overestimate the merit of materials, temperature-averaged entropy change (TEC) has recently been proposed as a more predictive figure of merit to identify the performance of the MCE materials, and it can be determined using the equation50:
where ΔTlift is the desired temperature span of the device, and Tmid is the temperature at the center of the average that maximizes TEC(ΔTlift) for the given ΔTlift. Figure 4e shows the variation of TEC with ΔTlift for the magnetic field along c axis. It is seen that the TEC decreases with increasing ΔTlift. The value of TEC(ΔTlift = 10 K) increases continuously and reaches 21.39 J kg−1 K−1 with Δμ0H = 7 T. The values of TEC(ΔTlift = 3 and 10 K) are also comparable to the previous works, such as La(Fe0.88Si0.12)1350 and HoNiGe351.
Based on above results, a phase diagram represented by the contour plot of dM/dμ0H vs μ0H curves is constructed for TbMn2Ge2 single crystal, and the data are shown in Fig. 4f. When \(T_{{\text{C}}}^{{{\text{Tb}}}}\) < T < \(T_{{\text{N}}}^{{{\text{inter}}}}\), the AFil-type magnetic structure is formed, and the spin alignment of adjacent Mn layers (interlayer) is antiparallel along c axis (right inset of Fig. 4f)19,20,21. Below \(T_{{\text{C}}}^{{{\text{Tb}}}}\), the Tb atoms order ferromagnetically along c axis and antiferromagnetically to the Mn sublattices (left inset of Fig. 4f). The magnetic ordering of Tb atoms accompanied by the magnetostriction effect is the mainly origination of the giant MCE. Additionally, the fully polarized FM state of Mn sublattices is established above the μ0HC when T > \(T_{{\text{C}}}^{{{\text{Tb}}}}\) (the middle inset of Fig. 4f). The coincide of μ0HC and \(\mu_{0} H^{\prime}_{{\text{C}}}\) curves implies that the remarkable magnetostriction effect is mainly due to the field-induced metamagnetic transition. The magnetic transition from AFil to FM state of Mn sublattices leads to the plateau behavior of the \(- \Delta S_{M}\) curves, and the giant MCE still retains without the ordering of Tb atoms. Further investigation of the magnetic structure evolution based on high magnetic field and neutron scattering measurement in TbMn2Ge2 single crystal is required to refine the phase diagram.
Conclusions
IN summary, we have studied the anisotropic magnetic property, magnetostriction, and the MCE in TbMn2Ge2 single crystal with the magnetic field along a and c axes. The magnetic ordering of Tb and Mn atoms results in the anomaly of ΔL/L and giant MCE near \(T_{{\text{C}}}^{{{\text{Tb}}}}\). A magnetic field-induced metamagnetic transition is observed along c axis above \(T_{{\text{C}}}^{{{\text{Tb}}}}\), which leads to the magnetostriction effect and the plateau behavior of the MCE over a wide temperature range. The calculated results of \(- \Delta S_{M}^{\max }\), RCP, and TEC(10) with the values of 24.02 J kg−1 K−1, 378.4 J kg−1, and 21.39 J kg−1 K−1 indicate that TbMn2Ge2 single crystal would be a promising candidate material for cryomagnetic refrigeration. Moreover, a μ0H-T phase diagram is established based on the magnetic behavior. The present results may provide some clue for searching novel magnetic refrigeration materials, and more studies need to be carried out to achieve a trade-off between the performance and cost, e.g., doping with light rare earth elements. Meanwhile, the temperature range where the MCE occurs needs to be further increased.
Data availability
The datasets generated and/or analysed during the current study are available in the [Crystallography Open Database] repository, [3000405].
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Acknowledgements
This work is supported by the Young Scientists Fund of the National Natural Science Foundation of China (Grant No. 11704091), the Open Project of Guangxi Key Laboratory of Nuclear Physics and Nuclear Technology (Grant No. NLK2021-10), and the Open Project of Key Laboratory of Novel Materials for Sensor of Zhejiang Province (Grant No. ZJKLNMS2021010).
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S.H. and Z.M.T. designed the experiments. Y.M.B. synthesized the single crystals. K.Q.W. performed X-ray diffraction measurements. S.H. and D.X.H. carried out measurements of physical properties. S.H. and Z.M.T. analyzed the data and prepared the manuscript. All the authors have read and approved the final version of the manuscript.
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Huang, S., Bai, Y., Wan, K. et al. Anisotropic magnetic property, magnetostriction, and giant magnetocaloric effect with plateau behavior in TbMn2Ge2 single crystal. Sci Rep 12, 18727 (2022). https://doi.org/10.1038/s41598-022-23661-4
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DOI: https://doi.org/10.1038/s41598-022-23661-4
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