Magnetic behavior of cubic Dy4RhAl with respect to isostructural Dy4PtAl, revealing a novel 4f d-band interaction

“…There are magnetic-field-induced features as well, attributable to first-order transitions in most of these compounds. The experimental results presented in this article on Ho and Er compounds reveal fascinating magnetic and transport anomalies with an exceptional MCE, as inferred from the values of the isothermal entropy change (ΔS), in comparison with the values reported earlier for this family; this finding at Recent investigations on some members of this class of compounds have established that there are novel transport anomalies, not only in the magnetically ordered state, but also in the paramagnetic state [6][7][8][9][10][11]. Here, we focus on the heavy R members of the Pt-based family, R 4 PtAl, where the 4f states are far away from the Fermi level (thereby avoiding the complex, well-known phenomena due to 4f -hybridization in light rare-earths); Pt 5d electrons are expected to be weakly correlated, although possessing strong spin-orbit coupling.…”

“…This finding, therefore, reinforces [9] that the anisotropy of the (crystal-field-split) 4f orbital (that is, aspherical nature) plays a key role for such an enhancement. (ii) The peak values of these two Pt compounds are far higher than those of the respective member of the isomorphous Rh family as well [9][10][11]. In fact, a comparison of the peak values of ΔS between Pt and Rh families suggests that this is in We have derived isothermal entropy change, ∆S = S(H) − S(0), by integrating the plots of C/T, and the results obtained are shown in Figure 6c,f, for selected final fields.…”

“…Complexities of crystallography for this family have been discussed by Engelbert and Janka in the literature [5] and also presented in our earlier publication [7]. Recent investigations on some members of this class of compounds have established that there are novel transport anomalies, not only in the magnetically ordered state, but also in the paramagnetic state [6][7][8][9][10][11]. Here, we focus on the heavy R members of the Ptbased family, R4PtAl, where the 4f states are far away from the Fermi level (thereby avoiding the complex, well-known phenomena due to 4f-hybridization in light rare-earths); Pt 5d electrons are expected to be weakly correlated, although possessing strong spin-orbit coupling.…”

“…Extensive studies in recent years revealed that Gd4PtAl shows re-entrant spinglass behavior around 20 K below its Néel temperature (TN = 64 K) [6], whereas Tb4PtAl exhibits spin-glass features at the onset of the AF order at 50 K and an additional spinglass anomaly at a further lower temperature [7]. Curiously, the Dy analogue undergoes a ferromagnetic transition at (TC=) 32.6 K, indicating an unusual role of Pt 5d states on the magnetism of a rare-earth with well-localized 4f orbital [11], which transforms to a spinglass phase around 20 K [8]. There are magnetic-field-induced features as well, attributable to first-order transitions in most of these compounds.…”

“…The compounds of the type R 4 TX (T = transition metals and X = p-block metal) with the cubic Gd 4 RhIn-type structure [2][3][4][5] provide a new platform in the field of "frustrated magnetism", as multiple sites for R seem to favor a spin-glass state, competing with antiferromagnetism (AF) and ferromagnetism (F) [6][7][8][9][10][11]. The crystal structure is shown in Figure 1 to bring out the surrounding of the three R ions.…”

Magnetic and Transport Anomalies and Large Magnetocaloric Effect in Cubic R4PtAl (R = Ho and Er)

“…There are magnetic-field-induced features as well, attributable to first-order transitions in most of these compounds. The experimental results presented in this article on Ho and Er compounds reveal fascinating magnetic and transport anomalies with an exceptional MCE, as inferred from the values of the isothermal entropy change (ΔS), in comparison with the values reported earlier for this family; this finding at Recent investigations on some members of this class of compounds have established that there are novel transport anomalies, not only in the magnetically ordered state, but also in the paramagnetic state [6][7][8][9][10][11]. Here, we focus on the heavy R members of the Pt-based family, R 4 PtAl, where the 4f states are far away from the Fermi level (thereby avoiding the complex, well-known phenomena due to 4f -hybridization in light rare-earths); Pt 5d electrons are expected to be weakly correlated, although possessing strong spin-orbit coupling.…”

“…This finding, therefore, reinforces [9] that the anisotropy of the (crystal-field-split) 4f orbital (that is, aspherical nature) plays a key role for such an enhancement. (ii) The peak values of these two Pt compounds are far higher than those of the respective member of the isomorphous Rh family as well [9][10][11]. In fact, a comparison of the peak values of ΔS between Pt and Rh families suggests that this is in We have derived isothermal entropy change, ∆S = S(H) − S(0), by integrating the plots of C/T, and the results obtained are shown in Figure 6c,f, for selected final fields.…”

“…Complexities of crystallography for this family have been discussed by Engelbert and Janka in the literature [5] and also presented in our earlier publication [7]. Recent investigations on some members of this class of compounds have established that there are novel transport anomalies, not only in the magnetically ordered state, but also in the paramagnetic state [6][7][8][9][10][11]. Here, we focus on the heavy R members of the Ptbased family, R4PtAl, where the 4f states are far away from the Fermi level (thereby avoiding the complex, well-known phenomena due to 4f-hybridization in light rare-earths); Pt 5d electrons are expected to be weakly correlated, although possessing strong spin-orbit coupling.…”

“…Extensive studies in recent years revealed that Gd4PtAl shows re-entrant spinglass behavior around 20 K below its Néel temperature (TN = 64 K) [6], whereas Tb4PtAl exhibits spin-glass features at the onset of the AF order at 50 K and an additional spinglass anomaly at a further lower temperature [7]. Curiously, the Dy analogue undergoes a ferromagnetic transition at (TC=) 32.6 K, indicating an unusual role of Pt 5d states on the magnetism of a rare-earth with well-localized 4f orbital [11], which transforms to a spinglass phase around 20 K [8]. There are magnetic-field-induced features as well, attributable to first-order transitions in most of these compounds.…”

“…The compounds of the type R 4 TX (T = transition metals and X = p-block metal) with the cubic Gd 4 RhIn-type structure [2][3][4][5] provide a new platform in the field of "frustrated magnetism", as multiple sites for R seem to favor a spin-glass state, competing with antiferromagnetism (AF) and ferromagnetism (F) [6][7][8][9][10][11]. The crystal structure is shown in Figure 1 to bring out the surrounding of the three R ions.…”

Magnetic and Transport Anomalies and Large Magnetocaloric Effect in Cubic R4PtAl (R = Ho and Er)

Emergent Griffiths-phase-like behavior in the ball-milled nanocrystalline Dy4RhAl and its implication