Your search keyword '"Agostini, V"' showing total 2 results

1. Ultrasonic wave propagation in stratified media with helical symmetry.

Author

Ponti, S., Zvezdin, K., Scalerandi, M., Agostini, V., and Oldano, C.

Subjects

ULTRASONIC waves, HELICES (Algebraic topology), ELECTROMAGNETIC fields

Abstract

Stratified media with helicoidal symmetry are of great interest in optics. They have been obtained for the first time by Reusch in 1869 by superposing layers of mica and progressively changing their orientation along the stack. Among liquid crystals there are several phases with similar structure, e.g. the twisted grain boundary (TGB) phase, which is the exact analogue of the Reusch composite, the cholesteric and smectic-C phases showing a continuum rotation of the dielectric properties along the helix axis. For light propagating along the helix axis of these media. Maxwell equations admit an analytical solution. For oblique incidence only numerical approaches may be used to study the light propagation. In both cases the medium rotates the polarization plane. The aim of this work is to look for an elastic analogue of the optical rotation, which can be interpreted as a mode conversion between the shear components. The purpose is to exploit the wealth of information on this topics in the field of optics in the case of ultrasonic wave propagation. For the numerical calculations we adopt the Local Interaction Simulation Approach (LISA), which has been discussed in detail in previous QNDE Meetings. © 2000 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2000

2. Local interaction simulation approach to modelling nonclassical, nonlinear elastic behavior in solids.

Author

Scalerandi M, Agostini V, Delsanto PP, Van Den Abeele K, and Johnson PA

Abstract

Recent studies show that a broad category of materials share "nonclassical" nonlinear elastic behavior much different from "classical" (Landau-type) nonlinearity. Manifestations of "nonclassical" nonlinearity include stress-strain hysteresis and discrete memory in quasistatic experiments, and specific dependencies of the harmonic amplitudes with respect to the drive amplitude in dynamic wave experiments, which are remarkably different from those predicted by the classical theory. These materials have in common soft "bond" elements, where the elastic nonlinearity originates, contained in hard matter (e.g., a rock sample). The bond system normally comprises a small fraction of the total material volume, and can be localized (e.g., a crack in a solid) or distributed, as in a rock. In this paper a model is presented in which the soft elements are treated as hysteretic or reversible elastic units connected in a one-dimensional lattice to elastic elements (grains), which make up the hard matrix. Calculations are performed in the framework of the local interaction simulation approach (LISA). Experimental observations are well predicted by the model, which is now ready both for basic investigations about the physical origins of nonlinear elasticity and for applications to material damage diagnostics.

Published

2003