內容簡介
《統一理論和超對稱(第3版)》是作者依據其為馬裏蘭大學高年級研究生授課時所用的講義編著而成,詳細介紹瞭人們嘗試建立一個能夠描述自然界中各種基本相互作用的大統一理論的最新進展。《統一理論和超對稱(第3版)》包羅甚廣,涉及到粒子物理學中的大統一理論和超對稱理論中的許多議題,例如自發對稱破缺,大統一理論,超對稱性和超引力等。作者在簡要迴顧瞭基本粒子理論之後,詳細介紹瞭復閤誇剋,輕子,希格斯玻色子和CP破壞等論題,最後討論超對稱的大統一方案。這是《統一理論和超對稱(第3版)》的第三版,進一步修訂瞭書中內容,添入該領域的最新進展,特彆是近年來實驗方麵的諸多進展。對這些新進展的集中介紹很有意義,使得《統一理論和超對稱(第3版)》成為該領域中連接傳統理論與研究前沿的有益橋梁。無論對該領域的研究生還是對研究人員來講,《統一理論和超對稱(第3版)》都是一部很有價值的教科書和參考文獻。
內頁插圖
目錄
Preface to the Third Edition
Preface to the Second Edition
Preface to the First Edition
1 Important Basic Concepts in Particle Physics
1.1 Introduction
1.2 Symmetries and Currents
1.3 Local Symmetries and Yang-Mills Fields
1.4 Quantum Chromodynamic Theory of Strong Interactions
1.5 Hidden Symmetries of Weak Interactions
References
2 Spontaneous Symmetry Breaking
2.1 Symmetries and Their Realizations
2.2 Nambu-Goldstone Bosons for an Arbitrary Non-Abelian Group
2.3 Some Properties of Nambu-Goldstone Bosons
2.4 Phenomenology of Massless and Near-Massless Spin-0 Bosons
2.5 The Higgs-Kibble Mechanism in Gauge Theories
2.6 Group Theory of the Higgs Phenomenon
2.7 Renormalizability and Triangle Anomalies
References
3 The SU(2)L x U(1) Model
3.1 The SU(2)L x U(1) Model of Glashow, Weinberg, and Salam
3.2 Neutral-Current Interactions
3.3 Masses and Decay Properties of W and Z Bosons
3.4 Fermion Masses and Mixing
3.5 Higher-Order-Induced Flavor-Changing Neutral-Current Effects
3.6 The Higgs Bosons
3.7 SU(2)L x U(1) Model with Two Higgs Doublets
3.8 Puzzles of the Standard Model
3.9 Outline of the Various Scenarios
3.10 Beyond the Standard Model
References
4 CP Violation: Weak and Strong
4.1 CP Violation in Weak Interactions
4.2 CP Violation in Gauge Models: Generalities
4.3 The Kobayashi-Maskawa Model
4.4 Left-Right Symmetric Models of CP Violation
4.5 The Higgs Exchange Models
4.6 Strong CP Violation and the 0-Problem
4.7 Solutions to the Strong CP Problem without the Axion
4.8 Summary
References
5 Grand Unification and the SU(5) Model
5.1 The Hypothesis of Grand Unification
5.2 SU(N) Grand Unification
5.3 Sin2 Ow in Grand Unified Theories (GUT)
5.4 SU(5)
5.5 Grand Unification Mass Scale and Sin2θw at Low Energies
5.6 Detailed Predictions of the SU(5) Model for Proton Decay
5.7 Some Other Aspects of the SU(5) Model
5.8 Gauge Coupling Unification with Intermediate Scales before Grand Unification
References
6 Symmetric Models of Weak Interactions and Massive Neutrinos
6.1 Why Left-Right Symmetry?
6.2 The Model, Symmetry Breaking, and Gauge Boson Masses
6.3 Limits on MzR and rnwR from Charged-Current Weak Interactions
6.4 Properties of Neutrinos and Lepton-Number-Violating Processes
6.5 Baryon Number Nonconservation and Higher Unification
6.6 Sin2θw and the Scale of Partial Unification
6.7 Left-Right Symmetry——An Alternative Formulation
6.8 Higher Order Effects
6.9 Conclusions
References
7 SO(10) Grand Unification
7.1 Introduction
7.2 SO(2N) in an SU(N) Basis [3]
7.3 Fermion Masses and the "Charge Conjugation" Operator
7.4 Symmetry-Breaking Patterns and Intermediate Mass Scales
7.5 Decoupling Parity and SU(2)R Breaking Scales
7.6 Second Z Boson
References
8 Technicolor and Compositeness
8.1 Why Compositeness?
8.2 Technicolor and Electroweak Symmetry Breaking
8.3 Techni-Composite Pseudo-Goldstone Bosons
8.4 Fermion Masses
8.5 Composite Quarks and Leptons
8.6 Light Quarks and Leptons and t Hooft Anomaly Matching
8.7 Examples of t Hooft Anomaly Matching
8.8 Some Dynamical Constraints on Composite Models
8.9 Other Aspects of Composite Models
8.10 Symmetry Breaking via Top-Quark Condensate
References
9 Global Supersymmetry
9.1 Supersymmetry
9.2 A Supersymmetric Field Theory
9.3 Two-Component Notation
9.4 Superfields
9.5 Vector and Chiral Superfields
References
10 Field Theories with Global Supersymmetry
10.1 Supersymmetry Action
10.2 Supersymmetric Gauge Invariant Lagrangian
10.3 Feynman Rules for Supersymmetric Theories [3]
10.4 Allowed Soft-Breaking Terms
References
11 Broken Supersymmetry and Application to Particle Physics
11.1 Spontaneous Breaking of Supersymmetry
11.2 Supersymmetric Analog of the Goldberger Treiman Relation
11.3 D-Type Breaking of Supersymmetry
11.4 ORaifeartaigh Mechanism or F-Type Breaking of Supersymmetry
11.5 A Mass Formula for Supersymmetric Theories and the Need for Soft Breaking
References
12 Minimal Supersymmetric Standard Model
12.1 Introduction, Field Content and the Lagrangian
12.2 Constraints on the Masses of Superparticles
12.3 Other Effects of Superparticles
12.4 Why Go beyond the MSSM?
12.5 Mechanisms for Supersymmetry Breaking
12.6 Renormalization of Soft Supersymmetry-Breaking Parameters
12.7 Supersymmetric Left-Right Model
References
13 Supersymmetric Grand Unification
14 Local Supersymmetry (N = 1)
15 Application of Supergravity (N = 1) to Particle Physics
16 Beyond N = 1 Supergravity
17 Superstrings and Quark-Lepton Physics
Index
精彩書摘
three-quark bound states, whereas meson spectroscopy arises from nonrela tivistic quark-antiquark bound states. Accepting quarks as the constituents of hadrons, we have to search for a field theory that provides the bindingforce between the quarks.
In trying to understand the Fermi statistics for baryons (such as ), itbecame clear that if they are S-wave bound states, then the space part oftheir wave function is totally symmetric; since a particle such as consists of three strange quarks, and has spin 3/2, the spin part of its wave functionis symmetric. If there were no other degree of freedom, this would be indisagreement with the required Fermi statistics. A simple way to resolvethis problem is to introduce [11] a threefold degree of freedom for quarks,called color (quarks being color triplets) and assume that all known baryonsare singlet under this new SU(3). Since an SU(3)c-singlet constructed outof three triplets is antisymmetric in the interchange of indices (quarks), thetotal baryon wave function is antisymmetric in the interchange of any twoconstituents as required by Fermi statistics.
It is now tempting to introduce strong forces by making SU(3)c into alocal symmetry. In fact, if this is done, we can show that exchange of theassociated gauge bosons provides a force for which the SU(3)c color singletis the lowest-lying state; and triplet, sextet, and octet states all have highermass. By choosing this mass gap large, we can understand why excitedstates corresponding to the color degree of freedom have not been found.
While this argument in favor of an SU(3)c gauge theory of strong inter-action was attractive, it was not conclusive. The most convincing argumentin favor of SU(3)c gauge theory came from the experimental studies of deepinelastic neutrino and electron scattering off nucleons. These experimentsinvolved the scattering of very-high-energy (E) electronsand neutrinoswith the exchange of very high momentum transfers (i.e., q2 large). It wasfound that the structure functions, which are analogs of form factors forlarge q2 and E, instead of falling with q2, became scale-invariant functionsdepending only on the ratio q2/2mE. This was known as the phenomenonof scaling [12]. Two different theoretical approaches were developed to un-derstand this problem. The first was an intuitive picture called the partonmodel suggested by Feynman [13] and developed by Bjorken and Paschos[14], where it was assumed that, at very high energies, the nucleon can bethought of as consisting of free pointlike constituents. The experimentalresults also showed that these pointlike constituents were spin-l/2 objects,like quarks, and the scaling function was simply the momentum distri-bution function for the partons inside the nucleon. These partons couldbe identified with quarks, thus providing a unified description of the nu-cleon as consisting of quarks at low, as well as at high, energies. The maindistinction between these two energy regimes uncovered by deep inelas-tic scattering experiments is that at low energies the forces between thequarks are strong, whereas at high energies the forces vanish letting thequarks float freely inside the nucleons.
前言/序言
The new millennium has brought new hope and vigor to particle physics.The menacing clouds of despair and discontent that enveloped the fieldfollowing the collapse of SSC have all but vanished. The discovery of neu-trino mass has brought the first light of new physics beyond the standardmodel.
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