Non-Equilibrium Phase Transitions

Dynamical scaling is key to our understanding of 'far from equilibrium' relaxation. Where Volume 1 of this set covered the statics and dynamics of transitions into an absorbing state, this one treats relaxation phenomena far from equilibrium and ageing.

The importance of knowledge consists not only in its direct practical utility but also in the fact the it promotes a widely contemplative habit of mind; on this ground, utility is to be found in much of the knowledge that is nowadays labelled 'useless'. Bertrand Russel, In Praise of Idleness, London (1935) Why are scientists in so many cases so deeply interested in their work ? Is it merely because it is useful ? It is only necessary to talk to such scientists to discover that the utilitarian possibilities of their work are generally of secondary interest to them. Something else is primary. David Bohm, On creativity, Abingdon (1996) In this volume, the dynamical critical behaviour of many-body systems far from equilibrium is discussed. Therefore, the intrinsic properties of the - namics itself, rather than those of the stationary state, are in the focus of 1 interest. Characteristically, far-from-equilibrium systems often display - namical scaling, even if the stationary state isvery far from being critical. A 1 As an example of a non-equilibrium phase transition, with striking practical c- sequences, consider the allotropic change of metallic ?-tin to brittle ?-tin. At o equilibrium, the gray ?-Sn becomes more stable than the silvery ?-Sn at 13. 2 C. Kinetically, the transition between these two solid forms of tin is rather slow at higher temperatures. It starts from small islands of ?-Sn, the growth of which proceeds through an auto-catalytic reaction.

Focusses on simulation methods, scaling arguments and new methods using dynamical symmetries Reviews in detail existing non-perturbative quantitative results on non-equilibrium phase transitions

Autorentext
Malte Henkel, born in 1960, received his Master's degree from the University of Bonn in 1984, and his PhD in 1987, when he also won the annual prize of the Minerva Foundation. From that year onward he has been a long-term visitor in many institutes, including the ITP at Santa Barbara, USA, the SPhT at Saclay, France, and the universities of Oxford, UK, Vienna, Austria, Padova, Italy, and Lisbon, Portugal. In 1995 he was appointed a professor at the University of Nancy I. His current research encompasses equilibrium and non-equilibrium phase transitions, using field-theoretical and numerical methods in general. In particular, his current focus is on dynamical scaling behaviour realised in ageing phenomena far from equilibrium. He has published well over a hundred articles and three monographs, one of which is Volume I of this set.

Inhalt

1. Ageing phenomena; 2. Exactly solvable models; 3. Simple ageing: an overview; 4. Local scale-invariance I: z = 2; 5. Local scale invariance II: z 2; 6. Lifshitz Points: Strongly Anisotropic Equilibrium Critical Points. Appendices: A. Equilibrium Models, D. Langevin Equations and Path Integrals, I. Cluster Algorithms: Competing Interactions. J. Fractional Derivatives. K. Conformally Invariant Interacting Fields. L. Lie Groups and Lie Algebras: a Reminder. M. On the Central Limit Theorem. Q. Lexique/Lexicon. Solutions. Frequently Used Symbols. Abbreviations. References. List of Tables. List of Figures. Index