by Kim Christensen (Imperial College London, UK) & Nicholas R Moloney (Imperial College London, UK)

Table of Contents (132k)
Preface (114k)
Chapter 1: Percolation (4,746k)

This book provides a challenging and stimulating introduction to the contemporary topics of complexity and criticality, and explores their common basis of scale invariance, a central unifying theme of the book.

Criticality refers to the behaviour of extended systems at a phase transition where scale invariance prevails. The many constituent microscopic parts bring about macroscopic phenomena that cannot be understood by considering a single part alone. The phenomenology of phase transitions is introduced by considering percolation, a simple model with a purely geometrical phase transition, thus enabling the reader to become intuitively familiar with concepts such as scale invariance and renormalisation. The Ising model is then introduced, which captures a thermodynamic phase transition from a disordered to an ordered system as the temperature is lowered in zero external field. By emphasising analogies between percolation and the Ising model, the reader's intuition of phase transitions is developed so that the underlying theoretical formalism may be appreciated fully. These equilibrium systems undergo a phase transition only if an external agent finely tunes certain external parameters to particular values.

Besides fractals and phase transitions, there are many examples in Nature of the emergence of such complex behaviour in slowly driven non-equilibrium systems: earthquakes in seismic systems, avalanches in granular media and rainfall in the atmosphere. A class of non-equilibrium systems, not constrained by having to tune external parameters to obtain critical behaviour, is addressed in the framework of simple models, revealing that the repeated application of simple rules may spontaneously give rise to emergent complex behaviour not encoded in the rules themselves. The common basis of complexity and criticality is identified and applied to a range of non-equilibrium systems. Finally, the reader is invited to speculate whether self-organisation in non-equilibrium systems might be a unifying concept for disparate fields such as statistical mechanics, geophysics and atmospheric physics.

Visit http://www.complexityandcriticality.com for animations for the models in the book (available for Windows and Linux), solutions to exercises, as well as a list with corrections.

• Percolation:
  • Percolating Phase Transition
  • Percolation in One Dimension
  • Percolation on the Bethe Lattice
  • Percolation in Two Dimensions
  • Geometric Properties of Clusters
  • Scaling Ansatz, Scaling Functions and Scaling Relations
  • Finite-Size Scaling
  • Universality
  • Real-Space Renormalisation Group
• Ising Model:
  • Review of Thermodynamics and Statistical Mechanics
  • Symmetry Breaking
  • Ferromagnetic Phase Transition
  • Ising Model in One Dimension
  • Mean-Field Ising Model
  • Ising Model in Two Dimensions
  • Landau Theory of Continuous Phase Transitions
  • Scaling Ansatz, Scaling Functions and Scaling Relations
  • Universality
  • Real-Space Renormalisation Group
• Self-Organised Criticality:
  • Non-equilibrium steady state system
  • BTW Model in One Dimension
  • Mean-Field Theory of the BTW Model
  • Branching Process
  • Scaling Ansatz, Scaling Functions and Scaling Relations
  • BTW Model in Two Dimensions
  • A Rice Pile Experiment and the Oslo Model
  • Earthquakes and the OFC Model
  • Rainfall
  • Self-Organised Criticality as a Unifying Principle