Negative magnetization in the medium-entropy Pr1/3Dy1/3Ho1/3CrO3 and PrCrO3 ceramics: comparative crystal structure, optic, dielectric and magnetic properties

In recent years, raising investigation activity in entropy-stabilized ceramic oxides has been driven by their innovative approach to designing a thermodynamically stable multi-element system, which provides a new focus on investigating complex functional materials. Especially, complex and singular physical properties of orthochromite have generated rising research in recent years. Of this family, the PrCrO3, DyCrO3, and HoCrO3 systems are particularly interesting since, below Néel temperature (TN), they present negative magnetization in the ZFC mode. Here, we have employed this approach and designed a medium-entropy (MECs) Pr1/3Dy1/3Ho1/3CrO3 (PDH) ceramic to study not only whether the magnetic characteristics prevail, but also the state of optical and dielectric properties of this new compound. In addition, the physical properties studied were compared with the single PrCrO3 (PC) compound. These compounds were synthesized through a facile combustion synthesis route. The X-ray diffraction analysis, energy-dispersive X-ray spectroscopy (EDS), and surface scanning elemental mapping reveal that a single phase is stabilized and equimolar cations are homogeneously distributed in the PDH-MECs. We found that the disorder of cations in the A-site of the structure has no significant effect on the optical transition in the visible electromagnetic region and dielectric properties with respect to the simple compound PC. In contrast, the magnetic properties are strongly affected in the MECs-PDH compound. We found that the TN is tuned through the O–Cr–O angles and below the antiferromagnetic transition. The results suggest that the negative magnetization in the ZFC mode is an intrinsic feature in these compounds since the negative ZFC susceptibility below TN predominates despite the cationic disorder. Furthermore, their negative magnetic mechanism in both the MECs-PDH and PC compounds are discussed in terms of the Γ2(FxCyGz) magnetic configuration.


Introduction
In the last years, many studies from the theoretical and experimental points of view have been performed in orthochromites materials since a rich variety of physical properties have been found [1][2][3][4][5][6][7].
The considerable attention to these physical properties envisions potential applications in data storage, magnetic refrigeration, and sensor devices [8][9][10][11]. The crystal structure of the RCrO3 (R = Y or rare earth) family is iso-structural with orthorhombic perovskite-derived structures (space group Pnma).
The R substitution from La to Lu decreases the tolerance factor causing the cooperative octahedral rotation, and accordingly, the CrO 6 octahedral tilting is progressively reduced, stabilizing the orthorhombic structure [12,13]. This fact affects the superexchange coupling and, accordingly, the magnetic ordering, first through the Cr (3d) sublattice and, second through the rare earth sublattice (4f) at lower temperatures. In addition, the magnetic competition/ interaction between 'd' and 'f' sublattices gives rise to a wide variety of interesting phenomena, such as magnetostriction-induced polarization, spin reorientation, magnetization reversal (in zero field cooling, ZFC and field cooling, FC mode), and exchange bias effect [14][15][16][17][18][19]. These physical phenomena have been found in simple compounds. They can also be induced and tuned by the substitution of isovalent and aliovalent cations in the A and B-sites of the perovskite lattice of orthochromites [4,[20][21][22]. At present, the presence of these phenomena has not yet been well understood, and it is evident to apply new strategies that shed light on mechanisms involved in these phenomena with the aim of the development of new paths in materials science technologies.
In the last years, the emergence of high-entropy ceramics (HECs) has attracted attention in advanced materials science [23,24]. It has been reported that HECs can be a way to improve the physical properties through the substitution of 3, 5, or more cations in equimolar ratios in simple oxide sublattices or complex ceramic structures such as perovskite, garnet, spinel, and other layer-structural ceramics [24][25][26]. The number of chemical constituents in the equimolar ratio defines low, medium, and high configurational entropy ceramics [25]. Thus, in orthochromites ceramic compounds, as a result of the iso-structural behavior through the rare earth substitution, the physical phenomena can be shared in the same structure, and so, to reveal whether (the intrinsic physical properties) they depend on the rare earth molar ratio or the structural distortion caused by multiple cations substitution using the high-entropic ceramics (HECs) approach. Through this path, we have designed an entropic ceramic material from three equimolar chemical constituents at the A-site, with the chemical formula Pr 1/3 Dy 1/3 Ho 1/3 CrO 3 . The design of the entropic material is relevant since each of the individual systems, i.e., PrCrO 3 , DyCrO 3 , and HoCrO 3 compounds synthesized as fine particles, have the particular characteristic of presenting below of T N negative magnetization in the ZFC mode [19,[27][28][29]. This behavior is unusual and little understood. Besides, several studies have addressed it as an artifact [30]. These particular magnetic characteristics in each system have motivated us to design a unique ceramic system where the three randomly distributed cations share the 4c Wyckoff atomic positions of the orthorhombic structure. Thus, in this work, a study of the chemical and structural characteristics is carried out, as well as the study of the optical, dielectric, and magnetic properties of the medium entropic compound Pr 1/3 Dy 1/3 Ho 1/3 CrO 3 , which is compared with the PC base system. The results shown below indicate that the dielectric properties are slightly modified with the equimolar substitutions of Pr, Dy, and Ho. However, not magnetic properties, which show that the O-Cr-O angles tune the T N , and the negative magnetization in the ZFC mode prevails below T N , and it is discussed in terms of the Γ 2 (F x C y G z ) magnetic configuration.

Experimental procedure
Powder PrCrO 3 and the medium-entropy ceramic Pr 1/3 Dy 1/3 Ho 1/3 CrO 3 (hereafter called PC and MECs-PDH) samples were synthesized by the combustion method. Stoichiometric quantities of Pr 6 0 11 (Sigma Aldrich 99.9%), Ho(NO 3 ) 3 .5H 2 O, Dy(NO 3 ) 3 .xH 2 O, and Cr(NO 3 ) 3 .9H 2 O were mixed to form the compounds under study according to the following reaction: first, the stoichiometric Pr 6 O 11 was previously dissolved in 1:1 HNO 3 (Sigma-Aldrich 70%). Nitrate cations, and praseodymium previously dissolved were stirred, dissolved in deionized water, and gradually heated at 150 °C. The final solution containing the homogeneous cations was mixed with 10 mL (1 g: 10 mL) of 2-methoxiethanol (Sigma-Aldrich 99.8%). Then and then the cations in the solution were concentrated by evaporation and diluted (adding deionized water) several times until the excess of HNO 3 was completely removed. Finally, the dried gel was burnt in self-propagation combustion to form a loose fine (1) powder. The result combustion powder was calcinated at 1200 °C for 6 h in the air. The crystal structure of the samples was studied by X-ray diffraction (XRD) using a Bruker D2 phaser diffractometer, Bragg-Brentano (2θ-φ scan) para focusing geometry, applying Cu-Kα (10 mA, 30 kV) radiation. The XRD measurement was carried out with a 0.02° step in a range of 10-80° for 2θ at room temperature. The crystallographic phase was identified by comparison with the X-ray patterns of the ICSD database. Rietveld refinement was performed to determine the structural features for each composition using the TOPAS 3.1 software for powder diffraction data. Microstructure, EDX, and elemental mapping analysis in a JEOL 5400LV operated at 20 kV were carried out on MECs-PDH sample. A Perkin Elmer Lambda 365 UV-Vis spectrophotometer coupled with an integrating sphere accessory was used to find the optical band gap (E g ) for PC and PDH samples. The emission spectra were collected in the 200-1100 nm spectral range. The samples were palletized in stainless steel die (∅ = 6 mm) and sintered at 1350 °C for 8 h. Samples sintered were silver painted on the surface and cured in a furnace with a thermal program from room temperature to 500 °C at a heating rate of 10°/min. We use an LCR bridge (HP-4284A) to obtain the dielectric spectrum from room temperature to 550 °C in the 1-100 kHz frequency range. Magnetic measurements were obtained using SQUID based vibrating sample magnetometer (MPMS 3, Quantum Design). To minimize the remanent magnetization into the equipment's superconductor magnet, and assure no magnetization perturbation remained in the sample, the external applied field was always switched back to zero in a 10 Oe/sec rate by using an oscillate approach at the end of each measurement.

Results and discussion
Crystal and microstructural features Figure 1 (Upper panel) shows the X-ray diffraction patterns of the medium-entropic MECs-PDH along with PC samples (Bottom panel). The diffraction peaks in both samples were Rietveld fit, assuming an orthorhombic perovskite distorted structure with the Pnma space group. The absence of extra peaks confirms the phase purity of the samples. Crystallographic data from the final refinement as well as the corresponding set of the reliability factors, such as weighted profile R-factor, expected R-factor, and goodness of fit (R wp , R exp , and χ 2 ) are presented for both compounds in Table 1. It is seen that the Dy and Ho substitution in equimolar quantities decreases the 'b' and 'c' lattice parameters with an increase of the 'a' lattice parameter. The net result is a decrease in the volume cell from 230.64 for PC to 222.46 Å 3 for the MECs-PDH sample. It is reasonable to expect a decrease in the volume cell for the MECs-PDH concerning the PC compound since 66% of the cations at the A-site have been occupied with smaller ionic radii (Dy = 1.083 Å, Ho = 1.072 Å) than that of the Pr (1.179 Å) cation. The tolerance factor (t) is determined from the ionic radii of the perovs- Here R 3+ is the ionic radii average of rare earth cations, taking a coordination number of IX from Shannon's tables [31]. Thus, the calculated tolerance factor is about 0.882, slightly smaller than 0.907 for the PC compound. In addition, the changes in the octahedral, CrO 6 environment are evaluated through bond-length, bond-angle,  Table 1 for PC and MECs-PDH samples, respectively. We deduce from those internal crystallography parameters that the cell volume decrease by substituting the smaller ionic radii is mainly led by the two bond-angles, Cr -O-Cr (see inset of Fig. 1 [18,32]. Figure 2 shows the EDS spectrum and the surface scanning elemental mapping on the MECs-PDH pellet sample to investigate the distribution and homogeneity of the elements. The analysis demonstrates that all elements are uniformly distributed without any segregation or aggregation in the form of clusters or precipitates. The theoretical and experimental weight percentage ratios listed in the inset of Fig. 2 show that they are within the stoichiometric ranges considering the accuracy of the EDS technique.

Optical characterization
The design of new materials requires knowledge of optical properties to provide good performance in optoelectronic device applications [33]. The interaction between light and matter can cause electrons to move from one energy level to another, creating an electrical signal or absorbing/emitting light. Thus, in this section, through the UV-Vis spectra, we analyze the optical transitions and energy band gap for the PC and the MECs-PDH samples. Figure 3a shows the UV-Vis reflectance spectra around the ultraviolet (200-800 nm) range for PC and the medium-entropy PDH samples. It can be noticed from the spectra that the reflectance in the visible region is higher for the MECs-PDH sample compared to the PC sample.
In addition, the spectra show five main broad dips localized at ~3 65, ~ 454, ~ 612, ~ 692, and ~ 732 nm, being these signals stronger for the MECs-PDH sample (vertical dash line). The first signal at 365 nm is ascribed to the energy band gap (E g ). The more prominent two signals at ~ 454 and ~ 612 nm have been attributed to two optical transitions of Cr 3+ (d 3 ) in an octahedral crystal field of CrO 6 that correspond to: 4 A 2g → 4 T 1g and 4 A 2g → 4 T 2g in the visible spectrum. These two transitions have been observed in several orthochromites [5,[34][35][36], and all of them have been related to the effect of the crystal field in the Cr 3+ (d 3 ) octahedral environment of the Table 1 Lattice parameters, volume cell and refined atomic position as well as internal geometric parameters of the CrO 6 octahedral environment at room temperature for MECs-PDH and PC systems. The tilting was obtained according to ref. [60] The reliability factors of the refinement are: R wp (%) = 6.13 R(%) = 5. perovskite. At higher wavelengths shows two more weak transitions, which correspond to 4 A 2g → 2 T 1g (~ 612 nm) and 4 A 2g → 2 E g (~ 732 nm) related to spinforbidden [5,37,38]. The energy band gap (E g ) is evaluated by Kubelka-Munk (K-M) function [39,40] for the MECs-PDH, and it is compared with PC samples, given by; R is the reflectance, α is the absorption coefficient, and S is the dispersion coefficient. The E g can be evaluated using the K-M equation, where the electronic properties can be found in a large number of semiconductor materials generally applied to highly light-scattering and absorbing particles. The dispersion coefficient is weakly energy-dependent and within the energy range contained by the absorption edge. It can be assumed that F(R) is proportional to α by;  where A is a proportional constant, hν is the photon energy, and the power factor "n" takes values of 2 for the direct band gap and ½ for the indirect band gap. R. Mguedla et al. [41], suggested a direct optical band gap in the PC ceramic compound by using and rearranging the Tauc´s relation (Eq. 5). Thus, the direct energy band gap is evaluated for both compounds through [F(R)*hν] 2 vs. photon energy plot [42], as is shown in Fig. 3b. Extrapolating the drop curves to α = 0 yielded E g values of 3.15 and 2.90 eV for MECs-PDH and PC, respectively. Note a slightly larger value, of around 0.25 eV, for the entropic system concerning the PC compound. This slight difference in the E g should be related to the structural deformations caused by the equimolar disorder of the cations within the matrix. However, it is worth noting that the E g values are in good agreement with that deduced from the experimental reflectance spectrum even with that calculated from density-functional theory for homolog compounds [33,43,44]. Once revealed the electronic properties through the energy band gap, it is imperative to reveal the dielectric properties in both compounds.

Dielectric properties
Frequency dependence of dielectric constant (ε') and dielectric loss (tan δ) at 50, 100, 200, and 300 °C for MECs-PDH and PC samples are shown in Fig. 4a and b. In both compounds, the permittivity and dielectric loss curves show a very similar behavior where both magnitudes decrease rapidly with frequency, being more pronounced at low frequencies and high temperatures. In bulk ceramics, particularly orthochromites, this is due to space charge polarization at the grain boundaries generating a potential barrier. This fact led to higher values of the ε' and tan δ. The dielectric dispersion at low frequency can be explained by the dominance of grain boundaries effect rather than by the grains. This behavior is attributed to the Maxwell-Wagner (MW) type interfacial polarization [36,45,46]. The giant ε' values and higher Tan δ at low frequencies asserts the MW contribution in both systems. L. Boudad et al. [45], by impedance analysis, showed that the decrease and merging curves at higher frequencies could be due to the release of space charge polarization. Table 2 compares the magnitudes of the permittivity (ε), the dielectric loss (δ), and electric conductivity (σ) in both compounds. These results show that the cations configurational disorder does not have a significant effect on both physical parameters.

Magnetic properties
Temperature-dependence of the ZFC and FC magnetic susceptibility under applied fields of 0.1 and 1 kOe for PCO and MECs-PDH samples is shown in Fig. 5.
Note that in both systems, unusual behavior in the ZFC magnetic ground states is displayed. For the PC sample, the susceptibility shows a large splitting in the ZFC and FC curves below ~ 239 K. It has been reported that the antiferromagnetic G-type structure with spin canting of the Cr +3 (S = 3/2) ion occurs below ~ 240 K for PC [19,47,48]. However, the equimolar Pr, Dy, and Ho substitution produces a decrease of the T N down to 171 K. On the other hand, the ZFC magnetic susceptibility curves show negative magnetization, which are kept up to 1 kOe, taking a value of ~ −8 emu/mol for the PC sample. On the contrary, the negative magnetization in the ZFC-mode is weaker, taking values of ~ -4.3 emu/mol, and positive magnetization values at 1 kOe are maintained up to 100 Oe. However, it is reversed to positive magnetization when the applied magnetic field reaches 1 kOe in the ZFC-mode for the MECs-PDH sample. The inverse susceptibility, χ −1 -T for PC and -MECs-PDH, is shown in the inset of the bottom graph of Fig. 5.
Analyzing the paramagnetic state (T > T N ), the values of the magnetic parameters are obtained from the linear fitting of χ −1 -T using the Curie-Weiss law; χ mol (T) = C/(T-Θ cw ) where C is the Curie Constant and Θ cw is the Curie-Weiss temperature. The experimental values extracted from the fitting allow us to estimate the effective moments on the A-site through the following equations [49];   Equations 6 and 7 are used for PCO and MECs-PDH samples, respectively. The μ eff obtained from the fitting and those calculated through both equations are tabulated in Table 3. For PCO, the effective moment on the A-site (Pr 3+ ) is calculated (Eq. 6) from the experimental effective moment and assuming that the μ Cr 3+ takes the theoretical value of 3.87 μ B [50], which results in a value of μ eff = 3.80 μ B . The value is close to the magnetic ground state value for Pr 3+ ion (3.58 μ B ; S = 1) [50]. In the same way, the value of μ Cr 3+ is calculated from the total effective moment. It assumes the theoretical value of μ Pr 3+ (3.58 μ B ), which results in an effective moment value of 4.08 μ B , also close to the theoretical value for Cr 3+ ion (3.87 μ B S = 3/2) [50]. For the case of MECs-PDH, where rare-earth cations share 1/3 on the A-site and using Eq. 7 assuming the magnetic ground state for the Cr 3+ and the involved rare-earth, we obtain the theoretical magnetic moment on the A-site and the total effective moment of 8.27 and 9.13 μ B , respectively. The experimental data for the MECs-PDH sample shows a total effective moment of 9.32 μ B , which is quite close to the calculated theoretical value [50]. In a similar way to what was done for PCO, using the experimental magnetic moment and assuming the theoretical value of μ Cr 3+ , the magnetic moment on the A-site can be estimated, which results in 8.47 μ B , which is also close to the calculated theoretical value [50]. The contribution of each ion to the total magnetic moment can also be obtained, assuming that the rest of the ions take the theoretical magnetic value. For example, for μ Pr 3+ , solving Eq. 7 μ −μ Dy 3+ − μ Ho 3+ results in a value of 4.2 μ B . Following the same procedure, we obtain 11.25, 11.22, and 4.29 μ B . for Dy 3+ , Ho 3+ and Cr 3+ ions, respectively. These values are close to the theoretical effective moments, and they are listed in Table 3. This fact infers that the magnitude of the magnetic moments in the paramagnetic state of each one of the subcells corresponds to the magnetic moments of the rare earth cations as well as the Cr 3+ (d 3 ) ions distributed homogeneously and randomly in bulk. The paramagnetic state changes to antiferromagnetic ordering at ~ 239 and ~ 171 K and is observed as a drop in the χ −1 -T curves for the PCO and MECs-PDH samples, respectively (Inset Fig. 5). At these temperatures, the G-type antiferromagnetic order of the Cr 3+ -magnetic moment occurs. It is well known in rare-earth orthochromites that T N values decrease almost linearly from 288 K for LaCrO 3 to 110 K for LuCrO 3 , which is closely related to the ionic radius of the rare-earth at the A-site. It is accepted that the Cr -O -Cr bond angle is reduced from 180° due to cooperative octahedral tilting, which affecting the superexchange coupling and reducing the T N . As mentioned above, the equimolar Pr, Dy, and Ho substitutions produce a T N of ~ 171 K, which is close to ~ 175.6 K, taking into consideration the T N average of PrCrO 3 (~ 239 K), DyCrO 3 (~ 147 K), and HoCrO 3 (~ 141 K) [35,48,51].  [32,48,52].
Analyzing the magnetic regimen below T N , Fig. 5 shows a large splitting below 239 K and 171 K in the ZFC and FC curves at a low applied magnetic field (100 Oe) for PCO and MECs-PDH, respectively. Although the negative magnetization in the ZFC mode has created controversy in other systems, it has been proven to be an artifact [53]. However, the result shown here demonstrates that this is not the case and is consistent with other studies in PC compounds [19,54,55]. A recent study [19] discussed that the negative magnetization from 2 to T N ~ 239 K in the ZFC mode is intrinsic behavior in the PC compound. There, we infer that the primary mechanism that causes this phenomenon is related to the Bertaut Γ 2 (F x C y G z ) magnetic configuration as well as the poor correlation at low temperature between the paramagnetic rare earth sublattice and the antiferromagnetic order of the Crsublattice. This assumption motivates us to design a new material using the high entropy configurational approach. Thus, we find that DyCrO 3 and HoCrO 3 possess identical antiferromagnetic Γ 2 (F x C y G z ) configurations as PC from 2 K to T N [56]. P. Gupta et al. [27] and Y. L. Sue et al. [29] report a large negative magnetization in the ZFC mode below 147 K for DyCrO 3 and 141 K for HoCrO 3 , respectively. Here, we hypothesize, If the Γ 2 (F x C y G z ) magnetic configuration is responsible for this behavior on the PC compound, then the equimolar MECs-PDH ceramic compound should keep the Γ 2 (F x C y G z ) magnetic configuration. If so, this magnetic setting should strengthen or at least keep up the negative susceptibility below T N . In Fig. 5, the negative susceptibility infers two crucial statements in the equimolar MECs-PDH ceramic compound. The first suggests that the Γ 2 (F x C y G z ) magnetic configuration is maintained homogeneously in the orthorhombic structure, and the second confirms that the involved mechanism inducing the negative magnetization in the ZFC mode is strongly related to the Γ 2 (F x C y G z ) magnetic configuration. Recently, T. Sau et al. [57], studying the unusual behavior of SmCrO 3 by neutron diffraction measurements, revealed that the Γ 2 (F x C y G z ) magnetic configuration produces a local field in the z-direction (G z ), which could be responsible for the drop in magnetization around 40 K when spin reorientation occurs from Γ 4 (F z A y G x ) to Γ 2 (F x C y G z ). We infer that this local field, fundamentally in the Γ 2 (F x C y G z ) magnetic configuration, is responsible for the negative magnetization in the FC mode and under mechanisms not yet well understood in the ZFC. Furthermore, the equimolar random distribution of net magnetic moments of Pr, Dy, and Ho weaken the opposing uniaxial magnetic component (G z ) since the negative magnetization is not kept at an applied magnetic field of 1 kOe compared with the PC compound. The experimental results shown here indicate that when turning on the applied magnetic field (below 100 Oe) in ZFC mode, the Pr, Ho, Dy sublattice, and the Cr sublattice are uncorrelated, feeling the same applied magnetic field. However, an internal field at the Cr-sites as a consequence of Γ 2 (F x C y G z ) spin configuration exceeds the applied magnetic field during ZFC mode, leads to negative magnetization. As we have mentioned in previous studies [18,19,58], this hypothesis should be corroborated with neutron diffraction studies.
To complete the magnetic study, Fig. 6 shows magnetization hysteresis curves as a function of applied magnetic field (± 40 kOe) at 20 K for PC (upper panel) and MECs-PDH (bottom panel) samples. As expected, a robust ferromagnetic contribution as well as an exchange bias effect (EB), as a result of robust magnetic exchange anisotropy, is observed in the PC sample. The robust exchange anisotropy (EB effect) results from an exchange coupling between interfaces of weak ferromagnetic and antiferromagnetic domains in the bulk PC sample. The interfacial exchange anisotropy is observed as a shift of the coercive field (Hc) towards the right side of the upper M-H curve of Fig. 6. Notice that the positive EB is unusual since in homologous compounds, the EB is generally negative [18,58]. This effect can be qualitatively explained by a strongly ferromagnetic coupling of uncompensated magnetic moments at the AFM-FM interface during the applied magnetic field [59]. However, the magnitude of these magnetic features is not maintained when equimolar ratios of Dy and Ho are shared with the Pr site even though all three sublattices have a ferromagnetic (F x ) contribution in the antiferromagnetic ordering of the Cr 3+ sublattice. The decrease in both the weak hysteresis buckle in the magnetization curve and the exchange bias effect indicates that the weak ferromagnetic and the exchange anisotropy also decrease in the collinear antiferromagnetic ordering (G z ,C y ) in the MECs-PDH compound. This fact infers that the local deformation as a consequence of the difference in the ionic radii of cations in the A-site tends to cancel the robust ferromagnetic contribution (F x ) as well as the exchange anisotropy (EB) that occurs when only Pr exists in the orthochromite compound.

Conclusions
Medium-entropy MECs-PDH and PC ceramics were successfully synthesized by combustion method. The volume cell decreased for the PDH-MECs sample concerning the PC compound. Surface scanning elemental mapping showed homogenous random cations distribution on A-sites of the MECs-PDH crystal structure. The cationic disorder does not have a significant effect on optical transitions in the electromagnetic visible range. However, it does have an energy band gap from 2.90 for PC to 3.15 for MECs-PDH. The permittivity, dielectric loss, and electric conductivity from RT to 300 °C showed that the configurational disorder of the cations does not have a significant effect on these physical properties. In contrast, the magnetic properties explored at low temperatures reveal that such cationic disorder affects the antiferromagnetic transition and the magnetic susceptibility below T N . The drop of the T N from 239 for PC to 171 K for the MECs-PDH is driven by the Dy and Ho substitution trough of the decreasing of the O -Cr -O bond angle. It is found that the negative ZFC prevails in the MECs-PDH sample, which strongly infers that this unusual magnetic feature is an intrinsic condition related to the Γ 2 (F x C y G z ) spin configuration. In summary, the present study shows that the high entropy approach in designing new materials can provide new evidence of controversial magnetic phenomena that motivate researchers to develop a more comprehensive theory of reversal magnetization from practical and theoretical points of view. this licence, visit http://creativecommons.org/licenses/ by/4.0/.