2020
DOI: 10.1002/zamm.202000076
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Modeling of electrodynamic processes by means of mechanical analogies

Abstract: This study continues the line of earlier research in mechanical models of electrodynamic processes suggested in previous works. The basic steps we take to construct these models are: to formulate equations of a special type Cosserat continuum, and then to suggest analogies between quantities characterizing the stress–strain state of the continuum and quantities characterizing electrodynamic processes. In addition to the previously introduced mechanical analogies of the electric field vector and the magnetic in… Show more

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Cited by 14 publications
(34 citation statements)
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“…These consequences are important for us because below we use them for physical interpretation of the theory. As shown in Ivanova [19], taking the vector invariant of Equation () yields ×ωgoodbreak=ω·()boldΘtrboldΘEgoodbreak+dΘ×dt.$$\begin{equation} \nabla \times \bm{\omega } = \bm{\omega } \cdot \bigl (\bm{\Theta } - {\rm tr}\,\bm{\Theta }\, \mathbf {E} \bigr ) + \frac{d \bm{\Theta }_{\times }}{d t}. \end{equation}$$If we rewrite term ×ω$\nabla \times \bm{\omega }$ as ·false(boldE×ωfalse)$\nabla \cdot (\mathbf {E} \times \bm{\omega })$ and interpret tensor boldE×ω$\mathbf {E} \times \bm{\omega }$ as a flux tensor, then we can treat Equation () as a balance equation for vector boldΘ×$\bm{\Theta }_{\times }$.…”
Section: Basic Equations Of the Cosserat Continuummentioning
confidence: 83%
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“…These consequences are important for us because below we use them for physical interpretation of the theory. As shown in Ivanova [19], taking the vector invariant of Equation () yields ×ωgoodbreak=ω·()boldΘtrboldΘEgoodbreak+dΘ×dt.$$\begin{equation} \nabla \times \bm{\omega } = \bm{\omega } \cdot \bigl (\bm{\Theta } - {\rm tr}\,\bm{\Theta }\, \mathbf {E} \bigr ) + \frac{d \bm{\Theta }_{\times }}{d t}. \end{equation}$$If we rewrite term ×ω$\nabla \times \bm{\omega }$ as ·false(boldE×ωfalse)$\nabla \cdot (\mathbf {E} \times \bm{\omega })$ and interpret tensor boldE×ω$\mathbf {E} \times \bm{\omega }$ as a flux tensor, then we can treat Equation () as a balance equation for vector boldΘ×$\bm{\Theta }_{\times }$.…”
Section: Basic Equations Of the Cosserat Continuummentioning
confidence: 83%
“…The only difference is the rank of the tensor quantities. As shown in Ivanova [19], from Equations () and (), it follows that ddt()12boldΘT××boldΘbadbreak=×(boldΘ×bold-italicω).$$\begin{equation} \frac{d }{d t} {\left(\frac{1}{2}\,\bm{\Theta }^T \!\times \times \, \bm{\Theta }\right)} = - \nabla \times (\bm{\Theta } \times \bm{\omega }). \end{equation}$$Taking the trace of Equation (), we arrive at the conservation law for the second principal scalar invariant of tensor Θ : ddt[]12tr0.16emΘ2goodbreak−Θ··0.16emΘbadbreak=·[]bold-italicω·Θtr0.16emΘ0.16emboldE.$$\begin{equation} \frac{d}{d t} {\left[\frac{1}{2} {\left(\bigl ({\rm tr}\,\bm{\Theta }\bigr )^2 - \bm{\Theta } \cdot \cdot \, \bm{\Theta } \right)}\right]} = - \nabla \cdot \Bigl [\,\bm{\omega } \cdot \bigl (\bm{\Theta } - {\rm tr}\,\bm{\Theta }\, \mathbf {E} \bigr ) \Bigr ].…”
Section: Basic Equations Of the Cosserat Continuummentioning
confidence: 83%
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