Critical Behavior in Non-equilibrium Systems
Author: Benjamin Philip Lee
Publisher:
Published: 1994
Total Pages: 201
ISBN-13:
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Critical Dynamics
Author: Uwe C. Täuber
Publisher: Cambridge University Press
Published: 2014-03-06
Total Pages: 529
ISBN-13: 0521842239
DOWNLOAD EBOOKA comprehensive and unified introduction to describing and understanding complex interacting systems.
Field Theory of Non-Equilibrium Systems
Author: Alex Kamenev
Publisher: Cambridge University Press
Published: 2023-01-05
Total Pages: 514
ISBN-13: 1108846440
DOWNLOAD EBOOKThe physics of non-equilibrium many-body systems is a rapidly expanding area of theoretical physics. Traditionally employed in laser physics and superconducting kinetics, these techniques have more recently found applications in the dynamics of cold atomic gases, mesoscopic and nano-mechanical systems, and quantum computation. This book provides a detailed presentation of modern non-equilibrium field-theoretical methods, applied to examples ranging from biophysics to the kinetics of superfluids and superconductors. A highly pedagogical and self-contained approach is adopted within the text, making it ideal as a reference for graduate students and researchers in condensed matter physics. In this Second Edition, the text has been substantially updated to include recent developments in the field such as driven-dissipative quantum systems, kinetics of fermions with Berry curvature, and Floquet kinetics of periodically driven systems, among many other important new topics. Problems have been added throughout, structured as compact guided research projects that encourage independent exploration.
Complexity and Criticality
Author: Kim Christensen
Publisher: World Scientific Publishing Company
Published: 2005-10-03
Total Pages: 409
ISBN-13: 191129833X
DOWNLOAD EBOOKThis 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. Contents:Percolation:Percolating Phase TransitionPercolation in One DimensionPercolation on the Bethe LatticePercolation in Two DimensionsGeometric Properties of ClustersScaling Ansatz, Scaling Functions and Scaling RelationsFinite-Size ScalingUniversalityReal-Space Renormalisation GroupIsing Model:Review of Thermodynamics and Statistical MechanicsSymmetry BreakingFerromagnetic Phase TransitionIsing Model in One DimensionMean-Field Ising ModelIsing Model in Two DimensionsLandau Theory of Continuous Phase TransitionsScaling Ansatz, Scaling Functions and Scaling RelationsUniversalityReal-Space Renormalisation GroupSelf-Organised Criticality:Non-equilibrium steady state systemBTW Model in One DimensionMean-Field Theory of the BTW ModelBranching ProcessScaling Ansatz, Scaling Functions and Scaling RelationsBTW Model in Two DimensionsA Rice Pile Experiment and the Oslo ModelEarthquakes and the OFC ModelRainfallSelf-Organised Criticality as a Unifying Principle Readership: Students at all levels, researchers and instructors looking for an introduction to the ideas of complexity and criticality.
Non-Equilibrium Phase Transitions
Author: Malte Henkel
Publisher: Springer Science & Business Media
Published: 2008-11-27
Total Pages: 385
ISBN-13: 1402087659
DOWNLOAD EBOOKThis book describes two main classes of non-equilibrium phase-transitions: static and dynamics of transitions into an absorbing state, and dynamical scaling in far-from-equilibrium relaxation behavior and ageing.
Non-Equilibrium Dynamics in Chemical Systems
Author: C. Vidal
Publisher: Springer Science & Business Media
Published: 2012-12-06
Total Pages: 260
ISBN-13: 3642701965
DOWNLOAD EBOOKMarkedly apart from elementary particle physics, another current has been building up and cont i nuous ly growi ng within contemporary phys i cs for severa 1 decades, and even expanding into many other disciplines, especially chemistry, biology and, quite recently, economics. Several reasons account for this: presumably the most impor tant one lies in the fact that, whatever the specific problem, model or material concerned, the same basic mathematical features are always involved. In this way, a general phenomenology has emerged which, unlike thermodynamics, is no longer depen dent upon the details or specifics: what largely prevails is the nonlinear charac ter of the underlying dynamics. Perhaps we are witnessing the emergence of a "non linear physics"--In a way similar to the birth of "quantum physics" in the twen ties - a physics which deals with the general behaviour of systems, whatever they are or may be. Over the past fifteen years, chemical systems evolving sufficiently far from equilibrium have proved to be particularly well fitted to experimental research on nonlinear behaviour: oscillation, multistability, birhythmicity, chaotic evolution, spatial self-organization and hysteresis are displayed by chemical reactions whose number is growing each year. In this volume are collected the lectures, communica tions and posters (abstracts) presented at an international meeting entitled: "Non-Equilibrium Dynamics in Chemical Systems", held in Bordeaux (France), Septem ber 3 rd-lth, 1984.
Simulations of Phase Behavior in Non-equilibrium Systems
Author: Florian Dittrich
Publisher:
Published: 2023
Total Pages: 0
ISBN-13:
DOWNLOAD EBOOKNon-equilibrium systems cover a tremendously wide range of different systems, in experiments and in simulations as well as in the real world. The fact that these systems are not in thermodynamic equilibrium is in many cases responsible for unique effects and behavior. A fundamental understanding of non-equilibrium systems is crucial to gain insights into such behavior and exploit it in a manifold of use cases. A recent growth in attention to non-equilibrium systems is a consequence. Especially deep insights into the nature of certain non-equilibrium systems can be gained through the study of phase behavior in these very systems. To do so, this thesis utilizes computer simulations of different systems: Discrete and continuous active matter systems on the one hand and skyrmion lattices on the other hand. The active matter systems being discussed in this work consist of active particles. These particles are not only subject to Brownian motion but they are in addition “actively” performing directed motion, which drives the systems out of equilibrium. Active lattice gas models are studied as a discrete realization of such particles with comparably low computational effort. At sufficiently high activity they undergo a motility induced phase separation (MIPS) that closely resembles the gas-liquid transition known from equilibrium. However, a determination of critical points and exponents for different model realizations performed in this work showed some model dependent deviations from 2D Ising universality class. This raises the question, whether the concept of universality holds for active matter and non-equilibrium systems at all. The critical behavior of active Brownian particles (ABPs) around MIPS has already been studied before and showed even stronger deviations. In this work additional focus is put on quenches of ABPs from homogeneous phase right into the phase separated regime and to the critical point. Following the quench, the systems far-from-steady-state dynamics, structure growth and aging can be studied. Results obtained in this work appear to be similar to those observed during phase separation in the 2D Ising model. However, for the active lattice models, there are deviations in the case of quenches inside the coexistence regions. Skyrmion lattices consist of densely packed skyrmions. These topologically stabilized whirls of magnetization can be described as quasiparticles. By modelling them as soft disks similar to ABPs, the underlying interaction potential of experimental skyrmions was determined with the help of computer simulations in this work. Furthermore, different experimental skyrmion lattices were characterized according to their phase state and degree of hexagonal order with the help of a newly developed parameter. Thereby the onset of a hexatic phase was found.
Non-Equilibrium Phase Transitions
Author: Malte Henkel
Publisher: Springer Science & Business Media
Published: 2011-01-19
Total Pages: 562
ISBN-13: 9048128692
DOWNLOAD EBOOK“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 is very 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.
Dynamics: Models and Kinetic Methods for Non-equilibrium Many Body Systems
Author: John Karkheck
Publisher: Springer Science & Business Media
Published: 2012-12-06
Total Pages: 512
ISBN-13: 940114365X
DOWNLOAD EBOOKRecent years have witnessed a resurgence in the kinetic approach to dynamic many-body problems. Modern kinetic theory offers a unifying theoretical framework within which a great variety of seemingly unrelated systems can be explored in a coherent way. Kinetic methods are currently being applied in such areas as the dynamics of colloidal suspensions, granular material flow, electron transport in mesoscopic systems, the calculation of Lyapunov exponents and other properties of classical many-body systems characterised by chaotic behaviour. The present work focuses on Brownian motion, dynamical systems, granular flows, and quantum kinetic theory.
Non-perturbative Renormalization Group Approach to Some Out-of-Equilibrium Systems
Author: Malo Tarpin
Publisher: Springer Nature
Published: 2020-03-19
Total Pages: 217
ISBN-13: 3030398714
DOWNLOAD EBOOKThis thesis presents the application of non-perturbative, or functional, renormalization group to study the physics of critical stationary states in systems out-of-equilibrium. Two different systems are thereby studied. The first system is the diffusive epidemic process, a stochastic process which models the propagation of an epidemic within a population. This model exhibits a phase transition peculiar to out-of-equilibrium, between a stationary state where the epidemic is extinct and one where it survives. The present study helps to clarify subtle issues about the underlying symmetries of this process and the possible universality classes of its phase transition. The second system is fully developed homogeneous isotropic and incompressible turbulence. The stationary state of this driven-dissipative system shows an energy cascade whose phenomenology is complex, with partial scale-invariance, intertwined with what is called intermittency. In this work, analytical expressions for the space-time dependence of multi-point correlation functions of the turbulent state in 2- and 3-D are derived. This result is noteworthy in that it does not rely on phenomenological input except from the Navier-Stokes equation and that it becomes exact in the physically relevant limit of large wave-numbers. The obtained correlation functions show how scale invariance is broken in a subtle way, related to intermittency corrections.
