Влияние гигантской магнитострикции на динамический предел текучести в условиях высокоскоростной деформации

The high-strain rate deformation of crystals with giant magnetostriction is theoretically analyzed. It is shown that giant magnetostriction has a significant effect on the dynamic yield stress of crystals.

Ферромагнетизм в гетероструктуре ферромагнитная пленка железо-иттриевого граната/ферромагнитный интерметаллид

We report on the investigations of the magnetic properties and ferromagnetic resonance in the heterostructure consisting of an epitaxial yttrium iron garnet (Y_3Fe_5O_12) film and a nanometer rare-earth intermetallic superlattice comprised of the (TbCo_2/FeCo)_ n exchange-coupled layers. The (TbCo_2/FeCo)_ n superlattice exhibits the giant magnetostriction and the controlled magnetic anisotropy induced by a magnetic field or elastic stresses. The magnetic interaction of the films in the (TbCo_2/FeCo)_ n /Y_3Fe_5O_12 heterostructure has been experimentally established and the spin current flowing through their interface has been detected.

Room temperature giant magnetostriction in single-crystal nickel nanowires

Magnetostriction is the emergence of a mechanical deformation induced by an external magnetic field. The conversion of magnetic energy into mechanical energy via magnetostriction at the nanoscale is the basis of many electromechanical systems such as sensors, transducers, actuators, and energy harvesters. However, cryogenic temperatures and large magnetic fields are often required to drive the magnetostriction in such systems, rendering this approach energetically inefficient and impractical for room-temperature device applications. Here, we report the experimental observation of giant magnetostriction in single-crystal nickel nanowires at room temperature. We determined the average values of the magnetostrictive constants of a Ni nanowire from the shifts of the measured diffraction patterns using the 002 and 111 Bragg reflections. At an applied magnetic field of 600 Oe, the magnetostrictive constants have values of λ100 = −0.161% and λ111 = −0.067%, two orders of magnitude larger than those in bulk nickel. Using Bragg coherent diffraction imaging (BCDI), we obtained the three-dimensional strain distribution inside the Ni nanowire, revealing nucleation of local strain fields at two different values of the external magnetic field. Our analysis indicates that the enhancement of the magnetostriction coefficients is mainly due to the increases in the shape, surface-induced, and stress-induced anisotropies, which facilitate magnetization along the nanowire axis and increase the total magnetoelastic energy of the system.

Магнитные взаимодействия на границе оксидный ферромагнетик/ферромагнитный интерметаллид

The magnetic properties of heterostructures consisting of two films are investigated: the upper layer is rare-earth intermetallic superlattices consisting of exchange-coupled TbCo2 / FeCo layers, and the lower layer, either epitaxially grown La0.7Sr0.3MnO3 (LSMO) manganite optimally doped with strontium, or an epitaxial film of an iron-yttrium garnet Y3Fe5O12 (YFO). The material (TbCo2 / FeCo) n (TCFC) provides giant magnetostriction, a large value of the magnetomechanical coupling coefficient, controlled induced magnetic anisotropy, and spin-orientational transitions induced by a magnetic field or elastic stresses. Experimental studies have shown that the interlayer interaction of the heterostructure TCFC / LSMO has an antiferromagnetic character. An increase in the FMR line width in the structures was ob-served, caused by the spin current flowing through the interface between two films. In the TCFC/YFO heterostructure, an electric voltage induced in the TCFC intermetallic film was observed, caused by the reverse spin Hall effect under ferromagnetic resonance conditions.