PrefacePreface to the Third EditionGeneral Sources and ReferencesPART �� BASICIDEAS AND TECHNIQUES 1 Pertinent concepts and ideas in the theory of critical phenomena 1��1 Description of critical phenomena 1��2 Scaling and homogeneity 1��3 Comparison of various results for critical exponents 1��4 Universality��dimensionality��symmetry Exercises 2 Formulation of the problem of phase transitions in terms of functional integrals 2��1 Introduction 2��2 Construction of the Lagrangian 2��2��1 The real scalar field 2��2��2 Complexfield 2��2��3 A hypercubic n��vector model 2��2��4 Two coupled fluctuating fields 2��3 The parameters appearing in �� 2��4 The partition function��or the generating functional 2��5 Representation of the Ising model in terms of functional integrals 2��5��1 Definition of the model and its thermodynamics 2��5��2 The Gaussian transformation 2��5��3 The free part 2��5��4 Some properties of the free theory��a free Euclidean field theory in less than four dimensions 2��6 Correlation functions including composite operators Exercises 3 Functional integrals in quanturn field theory 3��1 Introduction 3��2 Functionalintegrals for a quantum��mechanical system with one degree of freedom 3��2��1 Schwinger's transformation function 3��2��2 Matrix elements��Green functions 3��2��3 The generating functional 3��2��4 Analytic continuation in time��the Euclidean theory 3��3 Functional integrals for the scalar boson field theory 3��3��1 Introduction 3��3��2 The generating functional for Green functions 3��3��3 The generating functional as a functional integral 3��3��4 The S��matrix expressed in terms of the generating functional Exercises 4 Perturbation theory and Feynman graphs 4��1 Introduction 4��2 Perturbation expansionin coordinate space 4��3 The cancellation of vacuum graphs 4��4 Rules for the computation ofgraphs 4��5 More general cases 4��5��1 The M��vector theory 4��5��2 Comments on fields with higher spin 4��6 Diagrammatic expansion in momentum space 4��7 Perturbation expansion of Green functions with composite operators 4��7��1 In coordinate space 4��7��2 In momentum space 4��7��3 Insertion at zero momentum Exercises 5 Vertex functions and symmetry breaking 5��1 Introduction 5��2 Connected Green functions and their generating functional 5��3 The mass operator 5��4 The Legendre transform and vertex functions 5��5 The generating functional and the potential 5��6 Ward��Takahashi identities and Goldstone's theorem 5��7 Vertex parts for Green functions with composite operators Exercises 6 Expansions in the number of loops and in the number of components 6��1 Introduction 6��2 The expansion in the number of loops as a power series 6��3 The tree ��Landau��Ginzburg��approximation 6��4 The one��loop approximation and the Ginzburg criterion 6��5 Mass and coupling constant renormalizationin the one��loop approximation 6��6 Composite field renormalization 6��7 Renormalization of the field at the two��loop level 6��8 The O��M����symmetric theory in the limit of large M 6��8��1 Generalremarks 6��8��2 The origin of the M��dependence of the coupling constant 6��8��3 Faithful representation of graphs and the dominant terms in����4�� 6��8��4 ����2�� in theinfinite M limit 6��8��5 Renormalization 6��8��6 Broken symmetry Appendix 6��1 The method of steepest descent and the loop expansion Exercises 7 Renormalization 7��1 Introduction 7��2 Some considerations concerning engineering dimensions 7��3 Power counting and primitive divergences 7��4 Renormalization of a cutoff ��4 theory 7��5 Normalization conditions for massive and massless theories 7��6 Renormalization constants for a massless theory to order two loops 7��7 Renormalization away from the critical point 7��8 Counterterms 7��9 Relevant and irrelevant operators 7��10 Renormalization of a ��4 theory with an O��M�� symmetry 7��11 Ward identities and renormalization 7��12 Iterative construction of counterterms Exercises 8 The renormalization group and scaling in the critical region 8��1 Introduction 8��2 The renormalization group for the critical ��massless�� theory 8��3 Regularization by continuation in the number of dimensions 8��4 Massless theory below four dimensions��the emergence of �� 8��5 The solution of the renormalization group equation 8��6 Fixed points�� scaling�� and anomalous dimensions 8��7 The approach to the fixed point��asymptotic freedom 8��8 Renormalization group equation above Tc��identification of v 8��9 Below the critical temperature��the scaling form of the equation of state 8��10 The specific heat��renormalization group equation for an additively renormalized vertex 8��11 The Callan��Symanzik equations 8��12 Renormalization group equations for the bare theory 8��13 Renormalization group equations and scaling in the infinite M limit Appendix 8��1 General formulas for calculating Feynman integrals Exercises 9 The computation of the critical exponents 9��1 Introduction 9��2 The symbolic calculation of the renormalization constants and Wilson functions 9��3 The ��expansion of the critical exponents 9��4 The nature of the fixed points ��universality 9��5 Scale invariance at finite cutoff 9��6 At the critical dimension ��asymptotic infrared freedom 9��7 �� expansion for the Callan��Symanzik method 9��8 ��expansion of the renormalization group equations for the bare functions 9��9 Dimensional regularization and critical phenomena 9��10 Renormalization by minimal subtraction of dimensional poles 9��11 The calculation of exponents in minimal subtraction Appendix 9��1 Calculation of some integrals with cutoff 9��2 One��Ioop integrals in dimensional regularization 9��3 Two��Ioop integrals in dimensional regularization ExercisesPART �� FURTHER APPLICATIONS AND DEVELOPMENTS