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現(xiàn)代粒子物理學(xué)導(dǎo)論(第三版)(英文影印版)
《中外物理學(xué)精品書(shū)系:現(xiàn)代粒子物理學(xué)導(dǎo)論(第三版)(英文影印版)》涵蓋了粒子物理各種方向,包括量子電動(dòng)力學(xué)、夸克模型、標(biāo)準(zhǔn)模型等等。在理論和實(shí)驗(yàn)兩方面都進(jìn)行了系統(tǒng)講解。此外,本書(shū)還著重討論了天體物理、宇宙學(xué)和粒子物理學(xué)的交叉研究,即天體粒子物理學(xué)。
《中外物理學(xué)精品書(shū)系:現(xiàn)代粒子物理學(xué)導(dǎo)論(第三版)(英文影印版)》適合粒子物理、核物理、天體物理等領(lǐng)域的研究者和研究生閱讀。
粒子物理依然是人類(lèi)探索微觀世界的前沿,某種意義上說(shuō)也是整個(gè)現(xiàn)代物理學(xué)的基礎(chǔ)!吨型馕锢韺W(xué)精品書(shū)系:現(xiàn)代粒子物理學(xué)導(dǎo)論(第三版)(英文影印版)》是一本內(nèi)容非常豐富的專著,對(duì)于粒子物理的研究者來(lái)說(shuō)是難得的參考書(shū)。對(duì)于初學(xué)者也是很好的教材。
。ò突固梗┓ㄒ澏,巴基斯坦國(guó)家物理中心教授。
Preface vii
1. Introduction 1 1.1 Fundamental Forces . 1 1.1.1 The Gravitational Force 2 1.1.2 The Weak Nuclear Force 2 1.1.3 The Electromagnetic Force . 3 1.1.4 The Strong Nuclear Force 4 1.2 Relative Strength of Four Fundamental Forces 4 1.3 Range of the Three Basic Forces 5 1.4 Classi_cation of Matter . 7 1.5 Strong Color Charges 9 1.6 Fundamental Role of \Charges" in the Uni_cation of Forces 10 1.7 Strong Quark-Quark Force . 16 1.8 Grand Uni_cation 18 1.9 Units and Notation 19 1.10 Problems . 21 1.11 References . 21 2. Scattering and Particle Interaction 23 2.1 Introduction 23 2.2 Kinematics of a Scattering Process . 26 2.3 Interaction Picture 31 2.4 Scattering Matrix (S-Matrix) 32 2.5 Phase Space 36 2.6 Examples . 39 2.6.1 Two-body Scattering 39 2.6.2 Three-body Decay 41 2.7 Electromagnetic Interaction . 50 2.8 Weak Interaction . 52 2.9 Hadronic Cross-section 55 2.10 Problems . 56 2.11 References . 58 3. Space-Time Symmetries 59 3.1 Introduction 59 3.1.1 Rotation and SO(3) Group . 60 3.1.2 Translation 62 3.1.3 Lorentz Group 63 3.2 Invariance Principle . 65 3.2.1 U Continuous 65 3.2.2 U is Discrete (e.g. Space Reection) 66 3.3 Parity . 66 3.4 Intrinsic Parity 68 3.4.1 Intrinsic Parity of Pion . 70 3.5 Parity Constraints on S-Matrix for Hadronic Reactions 71 3.5.1 Scattering of Spin 0 Particles on Spin 1 2 Particles 71 3.5.2 Decay of a Spin 0+ Particle into Three Spinless Particles Each Having Odd Parity . 72 3.6 Time Reversal 73 3.6.1 Unitarity . 74 3.6.2 Reciprocity Relation . 75 3.7 Applications 76 3.7.1 Detailed Balance Principle . 76 3.8 Unitarity Constraints 77 3.8.1 Two-Particle Partial Wave Unitarity 79 3.9 Problems . 85 3.10 References . 90 4. Internal Symmetries 91 4.1 Selection Rules and Globally Conserved Quantum Numbers 91 4.2 Isospin . 97 4.2.1 Electromagnetic Interaction and Isospin 100 4.2.2 Weak Interaction and Isospin 101 4.3 Resonance Production 101 4.3.1 _-resonance . 103 4.3.2 Spin of _ . 103 4.4 Charge Conjugation . 107 4.5 G-Parity 112 4.6 Problems . 113 4.7 References . 117 5. Unitary Groups and SU(3) 119 5.1 Unitary Groups and SU(3) . 119 5.2 Particle Representations in Flavor SU(3) 124 5.2.1 Mesons 126 5.2.2 Baryons 128 5.3 U-Spin . 132 5.4 Irreducible Representations of SU(3) 134 5.4.1 Young's Tableaux 135 5.5 SU(N) . 141 5.6 Applications of Flavor SU(3) 145 5.6.1 SU(3) Invariant BBP Couplings 145 5.6.2 VPP Coupling 146 5.7 Mass Splitting in Flavor SU(3) . 148 5.8 Problems . 154 5.9 References . 158 6. SU(6) and Quark Model 159 6.1 SU(6) . 159 6.1.1 SU(6) Wave Function for Mesons . 160 6.2 Magnetic Moments of Baryons . 164 6.3 Radiative Decays of Vector Mesons . 170 6.4 Radiative Decays (Complementary Derivation) 176 6.4.1 Mesonic Radiative Decays V = P + . 176 6.4.2 Baryonic Radiative Decay . 177 6.5 Problems . 179 6.6 References . 180 7. Color, Gauge Principle and Quantum Chromodynamics 181 7.1 Evidence for Color 181 7.2 Gauge Principle 184 7.2.1 Aharanov and Bohm Experiment . 186 7.2.2 Gauge Principle for Relativistic Quantum Mechanics 188 7.3 Non-Abelion Local Gauge Transformations (Yang-Mills) . 190 7.4 Quantum Chromodynamics (QCD) . 194 7.4.1 Conserved Current . 197 7.4.2 Experimental Determinations of _s(q2) and Asymptotic Freedom of QCD 199 7.5 Hadron Spectroscopy . 202 7.5.1 One Gluon Exchange Potential . 202 7.5.2 Long Range QCD Motivated Potential 205 7.5.3 Spin-Spin Interaction 209 7.6 The Mass Spectrum . 209 7.6.1 Meson Mass Relations 211 7.6.2 Baryon Mass Spectrum . 213 7.7 Problems . 217 7.8 References . 219 8. Heavy Flavors 221 8.1 Discovery of Charm . 221 8.1.1 Isospin 223 8.1.2 SU(3) Classi_cation . 223 8.2 Charm . 224 8.2.1 Heavy Mesons 224 8.2.2 The Fifth Quark Flavor: Bottom Mesons . 228 8.2.3 The Sixth Quark Flavor: The Top . 228 8.3 Strong and Radiative Decays of D_ Mesons 229 8.4 Heavy Baryons 232 8.5 Quarkonium 233 8.6 Leptonic Decay Width of Quarkonium . 237 8.7 Hadronic Decay Width 238 8.8 Non-Relativistic Treatment of Quarkonium 240 8.9 Observations . 245 8.10 Tetraquark 246 8.11 Problems . 249 8.12 References . 254 9. Heavy Quark E_ective Theory 255 9.1 E_ective Lagrangian . 255 9.2 Spin Symmetry of Heavy Quark . 259 9.3 Mass Spectroscopy for Hadrons with One Heavy Quark . 264 9.4 The P-wave Heavy Mesons: Mass Spectroscopy 269 9.5 Decays of P-wave Mesons 275 9.6 Problems . 277 9.7 References . 277 10. Weak Interaction 279 10.1 V ?? A Interaction 279 10.1.1 Helicity of the Neutrino . 281 10.2 Classi_cation of Weak Processes 281 10.2.1 Purely Leptonic Processes . 281 10.2.2 Semileptonic Processes . 283 10.2.3 Non-Leptonic Processes . 287 10.2.4 _-Decay . 288 10.2.5 Remarks . 289 10.2.6 Semi-Leptonic Processes 291 10.3 Baryon Decays 292 10.4 Pseudoscalar Meson Decays . 296 10.4.1 Pion Decay 296 10.4.2 Strangeness Changing Semi-Leptonic Decays . 297 10.5 Hadronic Weak Decays 299 10.5.1 Non-Leptonic Decays of Hyperons . 299 10.5.2 _I = 1/2 Rule for Hyperon Decays 302 10.5.3 Non-leptonic Hyperon Decays in Non-Relativistic Quark Model . 304 10.6 Problems . 307 10.7 References . 310 11. Properties of Weak Hadronic Currents and Chiral Symmetry 311 11.1 Introduction 311 11.2 Conserved Vector Current Hypothesis (CVC) . 311 11.3 Partially Conserved Axial Vector Current Hypothesis (PCAC) 314 11.4 Current Algebra and Chiral Symmetry . 317 11.4.1 Explicit Breaking of Chiral Symmetry . 320 11.4.2 An Application of Chiral Symmetry to Non- Leptonic Decays of Hyperons 323 11.5 Axial Anomaly 325 11.6 QCD Sum Rules . 327 11.7 Problems . 328 11.8 References . 329 12. Neutrino 331 12.1 Introduction 331 12.2 Intrinsic Properties of Neutrinos 332 12.3 Mass 332 12.3.1 Constraints on Neutrino Mass . 333 12.3.2 Dirac and Majorana Masses 337 12.3.3 Fermion Masses in the Standard Model (SM) and See-saw Mechanism . 339 12.4 Neutrino Oscillations . 343 12.4.1 Mikheyev-Smirnov-Wolfenstein E_ect . 345 12.4.2 Evolution of Flavor Eigenstates in Matter . 349 12.5 Evidence for Neutrino Oscillations . 351 12.5.1 Disappearance Experiments 351 12.5.2 Appearance Experiments 351 12.6 Neutrino Mass Models and Mixing Matrix and Symmetries 355 12.7 Neutrino Magnetic Moment . 360 12.8 Problems . 362 12.9 References . 363 13. Electroweak Uni_cation 365 13.1 Introduction 365 13.2 Spontaneous Symmetry Breaking and Higgs Mechanism . 366 13.2.1 Higgs Mechanism 368 13.2.2 Gauge Symmetry Breaking for Chiral U1U2 Group 369 13.3 Renormalizability . 372 13.4 Electroweak Uni_cation . 374 13.4.1 Experimental Consequences of the Electroweak Uni_cation 381 13.4.2 Need for Radiative Corrections . 382 13.4.3 Experiments which Determine sin2 _W 387 13.5 Decay Widths of W and Z Bosons . 389 13.6 Tests of Yang-Mills Character of Gauge Bosons 395 13.7 Higgs Boson Mass 399 13.8 Upper Bound . 399 13.8.1 Unitarity . 399 13.8.2 Finiteness of Couplings . 400 13.9 Standard Model, Higgs Boson Searches, Production at Decays 401 13.9.1 LEP-2 401 13.9.2 LHC and Tevatron . 402 13.10 Two Higgs Doublet Model (2HDM) . 406 13.11 GIM Mechanism . 411 13.12 Cabibbo-Kobayashi-Maskawa Matrix 414 13.13 Axial Anomaly 416 13.14 Problems . 421 13.15 References . 423 14. Deep Inelastic Scattering 425 14.1 Introduction 425 14.2 Deep-Inelastic Lepton-Nucleon Scattering . 427 14.3 Parton Model . 431 14.4 Deep Inelastic Neutrino-Nucleon Scattering 436 14.5 Sum Rules . 439 14.6 Deep-Inelastic Scattering Involving Neutral Weak Currents 446 14.7 Problems . 447 14.8 References . 450 15. Weak Decays of Heavy Flavors 451 15.1 Leptonic Decays of _ Lepton 451 15.2 Semi-Hadronic Decays of _ Lepton . 453 15.2.1 Special Cases . 454 15.3 Weak Decays of Heavy Flavors . 457 15.3.1 Leptonic Decays of D and B Mesons . 458 15.3.2 Semileptonic Decays of D and B Mesons . 459 15.3.3 (Exclusive) Semileptonic Decays of D and B Mesons 464 15.3.4 Weak Hadronic Decays of B Mesons 471 15.3.5 Inclusive Hadronic B Decays 476 15.3.6 Radiative Decays of Bq Mesons 478 15.4 Inclusive Hadronic Decays of D-Mesons 479 15.4.1 Scattering and Annihilation Diagrams . 480 15.5 Problems . 484 15.6 References . 487 16. Particle Mixing and CP-Violation 489 16.1 Introduction 489 16.2 CPT and CP Invariance . 492 16.3 CP-Violation in the Standard Model 494 16.4 Particle Mixing 497 16.5 K0 ?? _K0 Complex and CP-Violation in K-Decay . 504 16.6 B0 ?? _B0 Complex 511 16.7 CP-Violation in B-Decays 515 16.8 CP-Violation in Hadronic Weak Decays of Baryons 518 16.9 Problems . 522 16.10 References . 523 17. Grand Uni_cation, Supersymmetry and Strings 525 17.1 Grand Uni_cation 525 17.1.1 q2 Evolution of Gauge Coupling Constants and the Grand Uni_cation Mass Scale . 529 17.1.2 General Consequences of GUTS 531 17.2 Poincar_e Group and Supersymmetry 534 17.2.1 Introduction . 534 17.2.2 Poincar_e group . 537 17.2.3 Two-Component Weyl Spinors . 539 17.2.4 Spinor Algebra, Supersymmetry 540 17.2.5 Supersymmetric Multiplets . 542 17.3 Supersymmetry and Strings . 544 17.3.1 Introduction . 544 17.3.2 Supersymmetry . 545 17.4 String Theory and Duality 548 17.4.1 M-theory . 550 17.5 Some Important Results . 552 17.6 Conclusions 552 17.7 Problems . 552 17.8 References . 554 18. Cosmology and Astroparticle Physics 557 18.1 Cosmological Principle and Expansion of the Universe 557 18.2 The Standard Model of Cosmology . 559 G 18.3 Cosmological Parameters and the Standard Model Solutions 562 18.4 Accelerating Universe and Dark Energy 566 18.4.1 Evidence from Supernovae . 567 18.4.2 Evidence from CMB Data . 568 18.4.3 Quintessence . 571 18.4.4 Modi_ed Gravity 573 18.5 Hot Big Bang: Thermal History of the Universe 574 18.5.1 Thermal Equilibrium 574 18.5.2 The Radiation Era . 576 18.6 Freeze Out 581 18.7 Limit on Neutrino Mass . 584 18.8 Primordial Nucleosynthesis . 585 18.9 Ination 588 18.9.1 Horizon Problem . 588 18.9.2 Flatness Problem 590 18.9.3 Realization of Ination . 591 18.9.4 Slow-roll Ination 593 18.10 Baryogenesis . 595 18.10.1 Sakharov's Conditions 597 18.10.2 Various Scenarios for Baryogenesis . 598 18.10.3 Leptogenesis . 601 18.11 Problems . 606 18.12 References . 607 Appendix A Quantum Field Theory 609 A.1 Spin 0 Field 609 A.2 Spin 1/2 Particle . 611 A.2.1 Pauli Representation of Matrices 612 A.2.2 Weyl Representation of Matrices . 613 A.3 Trace of Matrices 616 A.4 Spin 1 Field 618 A.5 Massive Spin 1 Particle . 619 A.6 Feynman Rules for S-Matrix in Momentum Space . 620 A.7 Application of Feynman Rules 621 A.7.1 e+e??!Hadrons 624 A.7.2 ElectronScatteringanStructurelessSpin1=2Target625 A.8 Discrete Symmetries . 628 A.8.1 Charge Conjugation . 628 A.8.2 Space Reection . 631 Electron Scattering and Structureless Spin 1=2 Target 625 A.8.3 Time Reversal 632 A.9 Problems . 633 AppendixB Renormalization Group and Running Coupling Constant 639 B.1 Feynman Rules for Quantum Chromodynamics 639 B.2 Renormalization Group, Coupling Constant and Asymptotic Freedom . 640 B.3 Running Coupling Constant in Quantum Electrodynamics (QED) . 645 B.4 Running Coupling Constant for SU(2) Gauge Group . 646 B.5 Renormalization Group and High Q2 Behavior of Green's Function 647 B.5.1 Gluon Propagator 649 B.5.2 Fermion Propagator . 650 B.6 References for Appendices 652 Index 653 收起全部↑
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