Book contents
- Frontmatter
- Contents
- Preface
- 1 Random walks on graphs
- 2 Uniform spanning tree
- 3 Percolation and self-avoiding walk
- 4 Association and influence
- 5 Further percolation
- 6 Contact process
- 7 Gibbs states
- 8 Random-cluster model
- 9 Quantum Ising model
- 10 Interacting particle systems
- 11 Random graphs
- 12 Lorentz gas
- References
- Index
12 - Lorentz gas
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- 1 Random walks on graphs
- 2 Uniform spanning tree
- 3 Percolation and self-avoiding walk
- 4 Association and influence
- 5 Further percolation
- 6 Contact process
- 7 Gibbs states
- 8 Random-cluster model
- 9 Quantum Ising model
- 10 Interacting particle systems
- 11 Random graphs
- 12 Lorentz gas
- References
- Index
Summary
A small particle is fired through an environment of large particles, and is subjected to reflections on impact. Little is known about the trajectory of the small particle when the larger ones are distributed at random. The notorious problem on the square lattice is summarized, and open questions are posed for the case of a continuum of needlelike mirrors in the plane.
Lorentz model
In a famous sequence of papers of 1906, Hendrik Lorentz introduced a version of the following problem. Large (heavy) particles are distributed about ℝd. A small (light) particle is fired through ℝd, with a trajectory comprising straight-line segments between the points of interaction with the heavy particles. When the small particle hits a heavy particle, the small particle is reflected at its surface, and the large particle remains motionless. See Figure 12.1 for an illustration.
We may think of the heavy particles as objects bounded by reflecting surfaces, and the light particle as a photon. The problem is to say something non-trivial about how the trajectory of the photon depends on the ‘environment’ of heavy particles. Conditional on the environment, the photon pursues a deterministic path about which the natural questions include:
Is the path unbounded?
How distant is the photon from its starting point after time t?
For simplicity, we assume henceforth that the large particles are identical to one another, and that the small particle has negligible volume.
- Type
- Chapter
- Information
- Probability on GraphsRandom Processes on Graphs and Lattices, pp. 219 - 225Publisher: Cambridge University PressPrint publication year: 2010