We consider an evolution equation arising in the Peierls\u2013Nabarro model for crystal dislocation. We study the evolution of such a dislocation function and show that, at a macroscopic scale, the dislocations have the tendency to concentrate at single points of the crystal, where the size of the slip coincides with the natural periodicity of the medium. These dislocation points evolve according to the external stress and an interior repulsive potential
The formation and stability of dislocation patterns are interpreted on the basis of instabilities oc...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...
Crystal plasticity is the result of the motion and complex and effectively non-linear interactions o...
We consider an evolution equation arising in the Peierls–Nabarro model for crystal dislocation. We s...
We consider the equation v(t) = L(s)v - W'(v) + sigma(epsilon)(t,x) in (o,+infinity) x IR, where L...
We consider an equation motivated by crystal dynamics and driven by a strongly nonlocal elliptic ope...
In this paper we study the connection between four models describing dislocation dynamics: a general...
In this paper we study the connection between four models describing dislocation dynamics: a general...
We consider an evolution equation arising in the Peierls-Nabarro model for crystal dislocation. We s...
We study a parabolic differential equation whose solution represents the atom dislocation in a cryst...
Abstract. We consider the equation vt = Lsv −W ′(v) + σε(t, x) in (0,+∞)×R, where Ls is an integro-d...
We consider a simple discrete model for screw dislocations in crystals. Using a variational discrete...
We study a parabolic differential equation whose solution represents the atom dislocation in a cryst...
We consider an evolution equation arising in the PeierlsNabarro model for crystal dislocation. We st...
The dynamics of large amounts of dislocations governs the plastic response of crystalline materials....
The formation and stability of dislocation patterns are interpreted on the basis of instabilities oc...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...
Crystal plasticity is the result of the motion and complex and effectively non-linear interactions o...
We consider an evolution equation arising in the Peierls–Nabarro model for crystal dislocation. We s...
We consider the equation v(t) = L(s)v - W'(v) + sigma(epsilon)(t,x) in (o,+infinity) x IR, where L...
We consider an equation motivated by crystal dynamics and driven by a strongly nonlocal elliptic ope...
In this paper we study the connection between four models describing dislocation dynamics: a general...
In this paper we study the connection between four models describing dislocation dynamics: a general...
We consider an evolution equation arising in the Peierls-Nabarro model for crystal dislocation. We s...
We study a parabolic differential equation whose solution represents the atom dislocation in a cryst...
Abstract. We consider the equation vt = Lsv −W ′(v) + σε(t, x) in (0,+∞)×R, where Ls is an integro-d...
We consider a simple discrete model for screw dislocations in crystals. Using a variational discrete...
We study a parabolic differential equation whose solution represents the atom dislocation in a cryst...
We consider an evolution equation arising in the PeierlsNabarro model for crystal dislocation. We st...
The dynamics of large amounts of dislocations governs the plastic response of crystalline materials....
The formation and stability of dislocation patterns are interpreted on the basis of instabilities oc...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...
Crystal plasticity is the result of the motion and complex and effectively non-linear interactions o...