Mihhail BerezovskiEmbry-Riddle Aeronautical University · Department of Mathematics (Daytona Beach)
Mihhail Berezovski
PhD
About
31
Publications
2,708
Reads
How we measure 'reads'
A 'read' is counted each time someone views a publication summary (such as the title, abstract, and list of authors), clicks on a figure, or views or downloads the full-text. Learn more
368
Citations
Introduction
Additional affiliations
August 2015 - present
August 2011 - June 2015
August 2003 - June 2015
Education
August 2006 - June 2010
September 2003 - June 2006
September 1998 - June 2003
Publications
Publications (31)
A special mesh adaptation technique and a precise discontinuity tracking are presented for an accurate, efficient, and robust adaptive-mesh computational procedure for one-dimensional hyperbolic systems of conservation laws, with particular reference to problems with evolving discontinuities in solids. The main advantage of the adaptive technique i...
The construction of a two-dimensional finite volume
numerical scheme based on the representation of computational cells as thermodynamic systems is presented explicitly. The main advantage of the scheme is an accurate implementation of conditions at interfaces and boundaries. It is demonstrated that boundary conditions influence the wave motion eve...
The paper introduces the theoretical background of the mechanism of electromagnetic energy and power accumulation and its focusing in narrow pulses travelling along a transmission line with material parameters
variable in one space dimension and time. This mechanism may be implemented due to a special material geometry, namely, a distribution of tw...
In the paper, the finite element method and the finite volume method are used in parallel for the simulation of a pulse propagation in periodically layered composites beyond the validity of homogenization methods. The direct numerical integration of a pulse propagation demonstrates dispersion effects and dynamic stress redistribution in physical sp...
Dynamic materials are artificially constructed in such a way that they may vary their characteristic properties in space or in time, or both, by an appropriate arrangement or control. These controlled changes in time can be provided by the application of an external (non-mechanical) field, or through a phase transition. In principle, all materials...
The paper is devoted to evolving discontinuities in elastic solids. A discontinuity is represented as a singular set of material points. Evolution of a discontinuity is driven by the configurational force acting at such a set. The main attention is paid to the determination of the velocity of a propagating discontinuity. Martensitic phase transitio...
Numerical simulation of acoustic emission by crack propagation in 3-point bending tests is performed to investigate how the interaction of elastic waves generates a detectable signal. It is shown that the use of a kinetic relation for the crack tip velocity combined with a simple crack growth criterion provides the formation of waveforms similar to...
Thermoelastic wave propagation suggests a coupling between elastic deformation and heat conduction in a body. Microstructure of the body influences the both processes. Since energy is conserved in elastic deformation and heat conduction is always dissipative, the generalization of classical elasticity theory and classical heat conduction is perform...
Elastic wave propagation through diffraction gratings is studied numerically in the plane strain setting. The interaction of the waves with periodically ordered elastic inclusions leads to a self-imaging Talbot effect for the wavelength equal or close to the grating size. The energy localization is observed at the vicinity of inclusions in the case...
Results of numerical simulations of two-dimensional elastic wave propagation through gratings in a homogeneous medium are presented. The possible application of the self-imaging Talbot effect to the non-destructive testing is demonstrated.
Numerical simulations of the thermoelastic response of a microstructured material on a thermal loading are performed in the one-dimensional setting to examine the influence of temperature gradient effects at the microstructure level predicted by the thermoelastic description of microstructured solids (Berezovski et al. in J. Therm. Stress. 34:413–4...
The wave motion in micromorphic microstructured solids is studied. The mathematical model is based on ideas of Mindlin and governing equations are derived by making use of the Euler–Lagrange formalism. The same result is obtained by means of the internal variables approach. Actually such a model describes internal fields in microstructured solids u...
The asymptotic stability of solutions of the Mindlin-type microstructure model for solids is analyzed in the paper. It is shown that short waves are asymptotically stable even in the case of a weakly non-convex free energy dependence on microdeformation.
A series of numerical simulations is carried on in order to understand the accuracy of dispersive wave models for microstructured solids. The computations are performed by means of the finite-volume numerical scheme, which belongs to the class of wave-propagation algorithms. The dispersion effects are analyzed in materials with different internal s...
The dispersive wave motion in solids with microstructure is considered in the one-dimensional setting in order to understand better the mechanism of dispersion. It is shown that the variety of dispersive wave propagation models derived by homogenization, continualisation, and generalization of continuum mechanics can be unified in the framework of...
Wave propagation in materials with embedded two different microstructures is considered. Each microstructure is characterized by its own length scale. The dual internal variables approach is adopted yielding in a Mindlin-type model including both microstructures. Equations of motion for microstructures are coupled with the balance of linear momentu...
As a preliminary study to more complex situations of interest in small-scale technology, this paper envisages the elementary
propagation properties of elastic waves in one-spatial dimension when some of the properties (mass density, elasticity) may
vary suddenly in space or in time, the second case being of course more original. Combination of the...
We address possibilities of minimising environmental risks using statistical features of current-driven propagation of adverse
impacts to the coast. The recently introduced method for finding the optimum locations of potentially dangerous activities
(Soomere et al. in Proc Estonian Acad Sci 59:156–165, 2010) is expanded towards accounting for the s...
We study numerically the influence of the presence of a complex internal structure of laminates consisting of layers of different properties on the dynamic response of a material. The influence of the mutual position of different layers is demonstrated by example of double periodic laminates.
The basic ideas for describing the dispersive wave motion in microstructured solids are discussed in the one-dimensional setting
because then the differences between various microstructure models are clearly visible. An overview of models demonstrates
a variety of approaches, but the consistent structure of the theory is best considered from the un...
A linear model of the microstructured continuum based on Mindlin theory is adopted which can be represented in the framework
of the internal variable theory. Fully coupled systems of equations for macro-motion and microstructure evolution are represented
in the form of conservation laws. A modification of wave propagation algorithm is used for nume...
The basic time scales for current-induced net transport of surface water and associated time scales of reaching the nearshore in the Gulf of Finland, the Baltic Sea, are analysed based on Lagrangian trajectories of water particles reconstructed from three-dimensional velocity fields by the Rossby Centre circulation model for 1987–1991. The number o...
We study numerically the influence of the presence of a complex internal structure of laminates, consisting of layers of different properties and variable thickness, on the dynamic response of the material. The influence of the internal structure of laminate layers on the signal propagation is demonstrated by several examples for periodic and doubl...
The basic time scales for current-induced net transport of surface water and associated time
scales of reaching the nearshore in the Gulf of Finland, the Baltic Sea, are analysed based on
Lagrangian trajectories of water particles reconstructed from three-dimensional velocity fields by the
Rossby Centre circulation model for 1987–1991. The number o...
Results of numerical simulations of one‐dimensional wave propagation in microstructured solids are presented and compared with the corresponding results of wave propagation in given layered media. A linear microstructure model based on Mindlin theory is adopted and represented in the framework of the internal variable theory. Fully coupled systems...
Results of numerical experiments are presented in order to compare direct numerical calculations of wave propagation in a laminate with prescribed properties and corresponding results obtained for an effective medium with the microstructure modelling. These numerical experiments allowed us to analyse the advantages and weaknesses of the microstruct...
Modern advanced materials (composites, FGM, SMA, ...) are inhomogeneous by definition. Their properties depend on composition (microstructure). The composition may be rather simple or extremely complex depending on the fabrication of the materials. Material with microstructure needs a constitutive model for the description of the microstructure inf...
The paper aims at presenting a numerical technique used in simulating the propagation of waves in inhomogeneous elastic solids.
The basic governing equations are solved by means of a finite-volume scheme that is faithful, accurate, and conservative.
Furthermore, this scheme is compatible with thermodynamics through the identification of the notions...
Dynamic response of inhomogeneous materials exhibits new
effects, which often do not exist in homogeneous media. It is quite natural that most of studies of wave and front propagation in inhomogeneous materials are associated with numerical simulations. To develop a numerical algorithm and to perform the numerical simulations of moving fronts we ne...
Systematic experimental work [S. Zhuang, G. Ravichandran, D. Grady, J. Mech. Phys. Solids 51 (2003) 245–265] on laminated composites subjected to high velocity impact loading exhibits the dispersed wave field and the oscillatory behavior of waves with respect to a mean value. Such a behavior is absent in homogeneous solids. An approximate solution...