Анотація:
Spin dynamics in magnetic nanostructured materials is a topic of great current interest. To describe spin motions
in such magnetic systems, the phenomenological Landau–Lifshitz (LL), or the LL–Gilbert (LLG), equation
is widely used. Damping term is one of the dominant features of magnetization dynamics and plays an essential
role in these equations of motion. The form of this term is simple; however, an important question arises whether
it provides a proper description of the magnetization coupling to the thermal bath and the related magnetic fluctuations
in the real nanometre-scale magnetic materials. It is now generally accepted that for nanostructured systems
the damping term in the LL (LLG) equation fails to account for the systematics of the magnetization relaxation,
even at the linear response level. In ultrathin films and nanostructured magnets particular relaxation
mechanisms arise, extrinsic and intrinsic, which are relevant at nanometre-length scales, yet are not so efficient
in bulk materials. These mechanisms of relaxation are crucial for understanding the magnetization dynamics that
results in a linewidth dependence on the nanomagnet’s size. We give an overview of recent efforts regarding the
description of spin waves damping in nanostructured magnetic materials. Three types of systems are reviewed:
ultrathin and exchange-based films, magnetic nanometre-scale samples and patterned magnetic structures. The
former is an example of a rare case where consideration can be done analytically on microscopic footing. The
latter two are typical samples when analytical approaches hardly have to be developed and numerical calculations
are more fruitful. Progress in simulations of magnetization dynamics in nanometre-scale magnets gives
hopes that a phenomenological approach can provide us with a realistic description of spin motions in expanding
diverse of magnetic nanostructures.