Anomalous transport in itinerant metamagnets with structural disorder

“…The latter feature means that, contrary to common expectation, the external magnetic field enhances static magnetic disorder in the ferromagnetic system in its ground state. This unusual characteristic behavior was observed also in other Y 1−x R x Co 2 (R=Tb, Dy, Ho and Er) alloys [5,6]. The anomalous behavior of the low temperature conduction in Y 1−x R x Co 2 was explained by the interplay of metamagnetic instability of Co 3d itinerant electrons and structural disorder in the R sublattice, which induces a spatially random distribution of high and low Co 3d magnetization, leading to a partially ordered state of the 3d itinerant electron system [4,6].…”

“…Residual resistivity of the alloys ρ 0 rapidly increases with increasing x and attains a maximum value near x c , where MR and PR change their sign. At the maximum ρ 0 constitutes about 70% of the room-temperature value of total resistivity of the alloy [4,5,6]. Figure 1 depicts the magnetic filed (ρ(B)) and pressure (ρ(P )) dependencies of resistivity of Y 0.82 Gd 0.18 Co 2 alloy (x c = 0.12 for Y 1−x Gd x Co 2 system).…”

Effects of pressure and magnetic field on transport properties of Y_1−xR_xCo₂alloys (R=Gd, Tb, Dy, Ho and Er)

“…The latter feature means that, contrary to common expectation, the external magnetic field enhances static magnetic disorder in the ferromagnetic system in its ground state. This unusual characteristic behavior was observed also in other Y 1−x R x Co 2 (R=Tb, Dy, Ho and Er) alloys [5,6]. The anomalous behavior of the low temperature conduction in Y 1−x R x Co 2 was explained by the interplay of metamagnetic instability of Co 3d itinerant electrons and structural disorder in the R sublattice, which induces a spatially random distribution of high and low Co 3d magnetization, leading to a partially ordered state of the 3d itinerant electron system [4,6].…”

“…Residual resistivity of the alloys ρ 0 rapidly increases with increasing x and attains a maximum value near x c , where MR and PR change their sign. At the maximum ρ 0 constitutes about 70% of the room-temperature value of total resistivity of the alloy [4,5,6]. Figure 1 depicts the magnetic filed (ρ(B)) and pressure (ρ(P )) dependencies of resistivity of Y 0.82 Gd 0.18 Co 2 alloy (x c = 0.12 for Y 1−x Gd x Co 2 system).…”

Effects of pressure and magnetic field on transport properties of Y_1−xR_xCo₂alloys (R=Gd, Tb, Dy, Ho and Er)

“…2(b), and other heavy-rare-earth-based alloy systems. 11) This similarity implies that the region with nonhomogeneous magnetization of the Co 3d electron subsystem exists in the phase diagram of the light-rare-earth-based Y 1Àx Nd x Co 2 alloy system. In this region, there is an enhancement of 0 owing to electron scattering by the static disorder in Co 3d magnetization, as described by Eq.…”

“…[7][8][9][10][11][12][13] In particular, on approaching x c , a large increase in the residual resistivity 0 was observed in Y 1Àx R H…”

“…Moreover, an unusual positive magnetoresistance and a strong pressure effect on resistivity have been observed in the magnetically ordered region at x > x c . 10,11,[14][15][16] In previous papers, we proposed a theoretical model that explains the anomalous variations of low-temperature conduction with composition x, magnetic field B, and pressure P in Y 1Àx R x Co 2 alloys. 10,[16][17][18] A random distribution of magnetic R and nonmagnetic Y ions over the rare-earth sublattice in Y 1Àx R x Co 2 alloys creates spatially fluctuating effective field B eff ðrÞ ¼ B þ n fd M R ðrÞ acting on the 3d electron subsystem [here, B is the external magnetic field, M R ðrÞ the 4f magnetic moment at site r of the rare-earth sublattice, and n fd the 3d-4f exchange constant].…”

Pressure and Substitution Effects on Transport and Magnetic Properties of Y_1-xR_xCo₂Systems with Static Magnetic Disorder

Electrical resistivity and thermopower of ErCo₃under hydrostatic pressure