Add to ORKGAbstract. A dispersing billiard (Lorentz gas) and focusing billiards (in the form of a stadium) with time-dependent boundaries are considered. The problem of particle acceleration in such billiards is studied. For the Lorentz gas two cases of the time dependence are investigated: stochastic perturbations of the boundary and its periodic oscillations. Two types of focusing billiards with periodically forced boundaries are explored: a stadium with strong chaotic properties and a near-rectangle stadium. It is shown that in all cases billiard particles can reach unbounded velocities. Average velocities of the particle ensemble as functions of time and the number of collisions are obtained. 1
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
Closed billiards have long served as prototype systems in the field of clas-sical and quantum dynami...
We consider a family of stadium-like billiards with time-dependent boundaries. Two different cases o...
Billiards with time dependent boundaries are a natural generalization of the one dimensional Fermi a...
By means of a thermodynamic approach we analyze billiards in the form of the Lorentz gas with the op...
We study a two-particle circular billiard containing two finite-size circular particles that collide...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
AbstractThe dynamics of a driven stadium-like billiard is considered using the formalism of discrete...
A billiard is a dynamical system in which a particle alternates between motion in a straight line an...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
The unlimited energy growth ( Fermi acceleration) of a classical particle moving in a billiard with ...
We consider the free motion of a point particle inside a circular billiard with periodically moving ...
Recent results concerned with the energy growth of particles inside a container with slowly moving w...
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
Closed billiards have long served as prototype systems in the field of clas-sical and quantum dynami...
We consider a family of stadium-like billiards with time-dependent boundaries. Two different cases o...
Billiards with time dependent boundaries are a natural generalization of the one dimensional Fermi a...
By means of a thermodynamic approach we analyze billiards in the form of the Lorentz gas with the op...
We study a two-particle circular billiard containing two finite-size circular particles that collide...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
AbstractThe dynamics of a driven stadium-like billiard is considered using the formalism of discrete...
A billiard is a dynamical system in which a particle alternates between motion in a straight line an...
The dynamics of a driven stadium-like billiard is considered using the formalism of discrete mapping...
The unlimited energy growth ( Fermi acceleration) of a classical particle moving in a billiard with ...
We consider the free motion of a point particle inside a circular billiard with periodically moving ...
Recent results concerned with the energy growth of particles inside a container with slowly moving w...
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
We study the dynamics of one-particle and few-particle billiard systems in containers of various sha...
Closed billiards have long served as prototype systems in the field of clas-sical and quantum dynami...