Magnetocapacitance effect and magnetoelectric coupling in type-II multiferroic HoFeWO6

Abstract: We have investigated the multiferroicity and magnetoelectric (ME) coupling in HoFeWO 6 . With a noncentrosymmetric polar structure (space group Pna2 1 ) at room temperature, this compound shows an onset of electric polarization with an antiferromagnetic ordering at the Néel temperature (T N ) of 17.8 K. The magnetic properties of the polycrystalline samples were studied by DC and AC magnetization and heat capacity measurements. The metamagnetic behavior at low temperatures was found to be directly related to t… Show more

“…As noted at the outset, magnetocapacitance occurs when the capacitance of a device changes with respect to the applied magnetic field. The coupling of ferroelectricity and ferromagnetism is common in multiferroic materials that can lead to magnetocapacitance effects, − yet the BiInO 3 thin films discussed here are nonpolar, so this does not apply to the Ni/BiInO 3 /(Ba,Sr)­RuO 3 /NdScO 3 (110) o heterostructure discussed here. Again, as noted at the outset, according to the Maxwell–Wagner capacitor model, − nonmultiferroic materials can also exhibit magnetocapacitance effects.…”

“…Applied magnetic field-controlled capacitance effects are common to multiferroic materials and ferromagnetic/ferroelectric multilayer stacks, leveraging the coexistence and coupling of more than one ferroic order parameter, principally magneto-electric coupling. − It is now understood that with the generalization of the Maxwell–Wagner capacitor model, magnetocapacitance effects are possible even in nonmultiferroic materials. − Magnetocapacitance effects are expected in nonmultiferroic materials as a result of giant intrinsic magneto-resistance, interface effects, and bulk inhomogeneities …”

Magnetocapacitance at the Ni/BiInO₃ Schottky Interface

“…As noted at the outset, magnetocapacitance occurs when the capacitance of a device changes with respect to the applied magnetic field. The coupling of ferroelectricity and ferromagnetism is common in multiferroic materials that can lead to magnetocapacitance effects, − yet the BiInO 3 thin films discussed here are nonpolar, so this does not apply to the Ni/BiInO 3 /(Ba,Sr)­RuO 3 /NdScO 3 (110) o heterostructure discussed here. Again, as noted at the outset, according to the Maxwell–Wagner capacitor model, − nonmultiferroic materials can also exhibit magnetocapacitance effects.…”

“…Applied magnetic field-controlled capacitance effects are common to multiferroic materials and ferromagnetic/ferroelectric multilayer stacks, leveraging the coexistence and coupling of more than one ferroic order parameter, principally magneto-electric coupling. − It is now understood that with the generalization of the Maxwell–Wagner capacitor model, magnetocapacitance effects are possible even in nonmultiferroic materials. − Magnetocapacitance effects are expected in nonmultiferroic materials as a result of giant intrinsic magneto-resistance, interface effects, and bulk inhomogeneities …”

Magnetocapacitance at the Ni/BiInO₃ Schottky Interface

Effect of the electrical inhomogeneity on the magnetocapacitance sign change in the HoxMn1−xS semiconductors upon temperature and frequency variation

Structural and magnetocaloric properties in the aeschynite type GdCrWO6 and ErCrWO6 oxides