Principles of modern physics:
Gespeichert in:
| 1. Verfasser: | |
|---|---|
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Oxford
Alpha Science Internat.
2007
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| Ausgabe: | 2. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | getr. Zählung graph. Darst. |
| ISBN: | 9781842654224 |
Internformat
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| 100 | 1 | |a Saxena, A. K. |e Verfasser |0 (DE-588)139684115 |4 aut | |
| 245 | 1 | 0 | |a Principles of modern physics |c Ajay K. Saxena |
| 250 | |a 2. ed. | ||
| 264 | 1 | |a Oxford |b Alpha Science Internat. |c 2007 | |
| 300 | |a getr. Zählung |b graph. Darst. | ||
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Datensatz im Suchindex
| _version_ | 1804138590291099648 |
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| adam_text | CONTENTS PREFACE TO THE SECOND EDITION V/Z PREFACE TO THE FIRST EDITION
IX A CKNOWLEDGEMENTS XI 1. ONSET OF THE QUANTUM HYPOTHESIS 1.1 1.1
INTRODUCTION 1.1 1.2 MAXWELFS EQUATIONS 1.2 1.3 PHYSICAL SIGNIFICANCE OF
MAXWELPS EQUATIONS 1.3 1.4 ELECTROMAGNETIC WAVE AND ITS VELOCITY 1.3 1.5
TRANSVERSE NATURE OF ELECTROMAGNETIC WAVES 1.4 1.6 ELECTROMAGNETIC POWER
FLOW AND POYNTING VECTOR 1.6 1.7 CONCLUSIONS FROM THE ELECTROMAGNETIC
THEORY 1.7 1.8 BLACK BODY RADIATION 1.9 1.9 THE RAYLEIGH-JEANS FORMULA
1.11 1.10 ULTRAVIOLET CATASTROPHE 1.14 1.11 PLANCK S HYPOTHESIS 1.14
1.12 PLANCK S RADIATION FORMULA 1.14 1.13 WIEN S LAW AND RAYLEIGH JEAN S
LAW AS SPECIAL CASES OF PLANCK S LAW 1.16 1.14 WIEN S DISPLACEMENT LAW
FROM PLANCK S FORMULA 1.17 1.15 STEFAN S LAW FROM PLANCK S FORMULA 1.18
1.16 PROPERTIES OF PHOTONS 1.19 1.17 PHOTONS AND GRAVITY 1.20 1.18
PHOTOELECTRIC EFFECT 1.22 1.19 EINSTEIN S PHOTOELECTRIC EQUATION 1.25
1.20 COMPTON EFFECT (SCATTERING OF HARD X-RAYS OR Y-RAYS) 1.26 1.21 ROLE
OF CONSTANTS C AND H IN PHYSICS 1.28 1.22 THE ELECTRON VOLT 1.29 XIV
CONTENTS 2. RELATIVISTIC MECHANICS 2.1 THE SPACE TIME MONIFOLD 2.2
HOMOGENEITY OF SPACE AND TIME 2.3 MOTION OF FREE BODIES 2.4 FRAME
OFREFERENCE 2.5 GALELIAN TRANSFORMATIONS 2.6 NEWTONIAN RELATIVITY 2.7
THE VELOCITY OF LIGHT 2.8 FAILURE OF NEWTONIAN MECHANICS 2.9 NEWTONIAN
RELATIVITY AND ELECTROMAGNETISM 2.10 THE CONCEPT OF AETHER 2.11
MICHELSON-MORLEY EXPERIMENT 2.12 EINSTEIN S POSTULATES OF SPECIAL THEORY
OF RELATIVITY 2.13 LORENTZ - TRANSFORMATIONS 2.14 VELOCITY
TRANSFORMATION 2.15 LORENTZ FITZGERALD LENGTH - CONTRACTION 2.16 TIME
DILATION 2.17 PROPER TIME 2.18 ISOTROPY OF TIME 2.19 CONSEQUENCES OF THE
VELOCITY EXCEEDING THAT OF LIGHT 2.20 GEOMETRY OF SPACE-TIME (THE
MINKOWSKI REPRESENTATION OF THE LORENTZ TRANSFORMATION) 2.21 RELATIVITY
AND THE FUNDAMENTAL CONCEPTS OF NEWTONIAN MECHANICS 2.22 ENERGY-MOMENTUM
VECTOR 2.23 MOMENTUM FOUR-VECTOR AND FORCE FOUR-VECTOR 2.24 RELATION
BETWEEN MOMENTUM AND ENERGY 2.25 ENERGY EQUATION IN RELATIVITY 2.26
EQUIVALENCE OF ENERGY AND MASS 2.27 RELATIVISTIC FOUR VECTOR AND
D ALEMBERTIAN OPERATOR 2.28 RELATIVITY AND ELECTROMAGNETIC THEORY 2.29
COVARIANT FORM OF THE MAXWELL S ELECTROMAGNETIC EQUATIONS 2.30
RELATIVISTIC DOPPIER EFFECT 2.31 WORLD REGIONS AND THE LIGHT CONE 3.
ATOMIC STRUCTURE AND SPECTRA 3.1 ATOMIC VIEW OF MATTER 3.2 DISCHARGE OF
ELECTRICITY THROUGH GASES (CATHODE RAYS) 3.3 MILLIKAN S OIL DROP
EXPERIMENT FOR ELECTRON CHARGE 3.4 THE MASS OF ELECTRON 2.1 2.1 2.2 2.3
2.3 2.4 2.5 2.5 2.6 2.6 2.7 2.7 2.10 2.10 2.14 2.15 2.17 2.18 2.19 2.19
2.20 2.23 2.25 2.26 2.29 2.30 2.32 2.33 2.34 2.36 2.40 2.43 3.1 3.1 3.2
3.4 3.6 CONTENTS XV 3.5 POSITIVE RAYS 3.9 3.6 THOMSON S PARABOLA METHOD
FOR POSITIVE RAYS ANALYSIS 3.9 3.7 DISCOVERY OFLSOTOPES 3.12 3.8 ATOMIC
WEIGHT AND ATOMIC MASS 3.13 3.9 ATOMIC MODELS 3.13 3.10 RUTHERFORD S
EXPERIMENT AND ATOMIC MODEL 3.14 3.11 THE SPECTRA OF HYDROGEN 3.21 3.12
BOHR THEORY OF THE SPECTRUM OF THE HYDROGEN ATOM 3.22 3.13 DRAWBACKS OF
BOHR S THEORY 3.26 3.14 CORRECTION FOR THE FINITE MASS OF THE NUCLEUS
3.26 3.15 DISCOVERY OF HEAVY HYDROGEN 3.28 3.16 ATOMIC EXCITATION 3.29
3.17 THE FRANCK-HERTZ EXPERIMENT 3.30 3.18 BOHR S CORRESPONDENCE
PRINCIPLE 3.32 3.19 WILSON-SOMMERFELD RULES OFQUANTISATION 3.34 3.20
SOMMERFELD S ELLIPTICAL ORBITS 3.36 3.21 SOMMERFELD S RELATIVITY
CORRECTION 3.42 3.22 SHORTCOMINGS OF OLD QUANTUM THEORY 3.46 3.23 SPACE
QUANTISATION 3.47 3.24 WAVE NUMBERS FOR ALKALI SPECTRUM 3.53 3.25
SPECTROSCOPIC NOTATION (SODIUM SPECTRUM) AND ELECTRON SPIN 3.53 3.26 THE
L-S COUPLING 3.55 3.27 LANDE S VECTOR MODEL OF THE ATOM 3.55 3.28 J-J
COUPLING 3.57 3.29 SELECTION RULES 3.57 3.30 INTENSITY RULES 3.58 3.31
FINESTRUCTUREOFTHE// A LINE 3.58 3.32 FINE STRUCTURE OF SODIUM D LINE
3.59 3.33 THE STERN-GERLACH EXPERIMENT 3.60 4. THE BASIC QUANTUM
MECHANICS 4.1 4.1 DE BROGLIE S MATTER WAVES 4.2 4.2 ABSENCE OF MATTER
WAVES IN MACROSCOPIC WORLD 4.3 4.3 DAVISSON AND GERMER S EXPERIMENT ON
DIFFRAETION OF ELECTRONS 4.4 4.4 MATTER WAVES (DUE TO ELECTRONS) IN
ATOMS 4.6 4.5 IS THE WAVE PARTICLE DUALITY REAL? 4.7 4.6 QUANTUM
PROPERTIES OF MICRO PARTICLES 4.8 4.7 DEVELOPMENT OF THE QUANTUM
MECHANICS 4.10 4.8 PROBABILISTIC DESCRIPTION OF PHOTONS (DOUBLE SLIT
EXPERIMENT) 4.11 I CONTENTS 4.9 PARTICLEAVAVES IN CLASSICAL PHYSICS AND
QUANTUM PHYSICS 4.12 (PHYSICAL BASIS OF THE DOUBLE SLIT EXPERIMENT) 4.10
THE CONCEPT OF WAVE FUNCTION AND ITS PHYSICAL SIGNIFICANCE 4.15 4.11 THE
FORM OF WAVE FUNCTION FOR MATTER WAVE 4.15 (WAVE PACKET, GROUP VELOCITY
AND PHASE VELOCITY) 4.12 HEISCNBERG S UNCERTAINTY PRINCIPLE (POSITION -
MOMENTUM UNCERTAINTY) 4.18 4.13 FOURIER INTEGRAL THEOREM 4.20 4.14
ENERGY-TIME UNCERTAINTY 4.21 4.15 HEISENBERG S MICROSCOPE - EXPERIMENT
4.22 4.16 APPLICATIONS OF UNCERTAINTY PRINCIPLE 4.23 4.17 OPERATIONS OF
OBSERVATION 4.25 4.18 OPERATORS AND OBSERVATIONS 4.26 4.19 TWO PHYSICAL
POSTULATES 4.27 4.20 SCHRODINGER EQUATION (TIME DEPENDENT FORM) 4.28
4.21 COMMUTATION RELATIONS 4.30 4.22 TIMC-LNDEPENDENT SCHRODINGER
EQUATION (STEADY STATE FORM) 4.31 4.23 EQUATION OF CONTINUITY AND
PROBABILITY CURRENT DENSITY 4.32 4.24 ANGULAR MOMENTUM OPERATORS AND ITS
REPRESENTATION IN 4.33 SPHERICAL POLAR COORDINATE 4.25 EXPECTATION
VALUES 4.37 4.26 SCHWARTZ S INEQUALITY 4.40 4.27 DERIVATION OF
HEISENBERG S UNCERTAINTY PRINCIPLE USING COMMUTATION RELATIONS 4.41 4.28
APPLICATIONS OF SCHRODINGER S EQUATION 4.43 4.29 SCHRODINGER S
RELATIVISTIC WAVE EQUATION (KLEIN-GORDON EQUATION) 4.72 4.30 DIRAC S
RELATIVISTIC EQUATION 4.74 4.31 NEGATIVE ENERGY STATES 4.79 4.32 PAIR
CREATION AND PAIR ANNIHILATION 4.79 5. HYDROGEN ATOM AND PERIODIC TABLE
5.1 5.1 SCHRODINGER EQUATION FOR THE HYDROGEN ATOM 5.1 5.2 SOLUTION OF
SCHRODINGER EQUATION 5.2 5.3 QUANTUM NUMBERS 5.11 5.4 EIGEN FUNCTIONS
5.12 5.5 PAULI EXCLUSION PRINCIPLE 5.19 5.6 SHELLS AND SUBSHELLS IN
ATOMS 5.20 5.7 AUFBAU PRINCIPLE AND THE PERIODIC TABLE 5.21 5.8
PROMINENT FEATURES OF THE PERIODIC TABLE 5.22 5.9 S,P,DJ BLOCK ELEMENTS
5.24 XVUEI CONTENTS 8.16 CRYSTAL MOMENTUM 8.77 8.17 THE CONCEPT OF
EFFECTIVE MASS 8.78 8.18 THE CONCEPT OFHOLES 8.79 8.19 SOMMERFELD S
ELECTRON THEORY OF METALS 8.81 8.20 THE DENSITY OF STATES FUNCTION 8.84
8.22 ELECTRONIC SPECIFIC HEAT 8.95 8.23 PAULI PARAMAGNETISM 8.97 8.24
HALL EFFECT 8.99 8.25 FERMI SURFACES 8.104 8.26 VARIATIONS IN THE FREE
ELECTRON FERMI-SURFACE OF A SQUARE LATTICE 8.106 ACCORDING TO THE
VALENCE OF THE METAL 8.27 FERMI SURFACE AND BRILLOUIN ZONES 8.108 8.28
DIVALENT METALS 8.109 8.29 CONSTANT ENERGY CONTOURS 8.110 8.30 PHONONS
8.111 8.31 VIBRATIONS OF A LINEAR (ONE-DIMENSIONAL) MONATOMIC CHAIN
8.111 8.32 LATTICE VIBRATIONS OF A LINEAR DIATOMIC CHAIN 8.115 8.33
SPECIFIC HEAT OF SOLIDS 8.120 8.34 SEMICONDUCTORS 8.129 8.35 P-N
JUNCTION 8.140 8.36 DIFFUSION AND DRIFT CURRENTS IN SEMICONDUCTORS (AND
EINSTEIN S RELATION) 8.148 8.37 SOLAR CELL 8.149 8.38 HALL EFFECT IN
SEMICONDUCTORS 8.154 9. IMPERFECTIONS IN CRYSTALS 9.1 9.1 WHAT IS AN
IMPERFECTION? 9.1 9.2 IMPORTANCE OF LATTICE DEFECTS (IMPERFECTIONS) 9.1
9.3 TYPESOF IMPERFECTIONS 9.2 9.4 POINT DEFECTS 9.2 9.5 POLARONS 9.9 9.6
EXCITONS 9.10 9.7 DISLOCATIONS 9.13 9.8 PLANE OR SURFACE DEFECTS 9.17
10. MAGNETIC PROPERTIES OF MATERIALS 10.1 10.1 MAGNETIC MATERIALS 10.1
10.2 ORIGIN OF PERMANENT MAGNETIC DIPOLES IN MATTER 10.2 10.3 CONCEPT OF
MAGNETIC SUSCEPTIBILITY 10.3 10.4 MAGNETIC QUANTITIES 10.4 10.5
CLASSIFICATION OF MAGNETIC MATERIALS 10.5 CONTENTS XJX 10.6 LANGEVIN S
THEORY OF DIAMAGNETISM 10.6 10.7 QUANTUM THEORY OF DIAMAGNETISM 10.9
10.8 LANGEVIN S THEORY OF PARAMAGNETISM 10.12 10.9 QUANTUM THEORY OF
PARAMAGNETISM 10.15 10.10 FERROMAGNETISM 10.19 10.11 HEISENBERG^
EXCHANGE INTERACTIONS IN FERROMAGNETS 10.23 10.12 FERROMAGNETIC DOMAINS
AND HYSTERISIS 10.25 10.13 CLOSURE DOMAINS 10.26 10.14 BLOCHWALL 10.28
10.15 ANTIFERROMAGNETISM 10.28 10.16 FERRIMAGNETISM 10.33 10.17 SOFT AND
HARD MAGNETIC MATERIALS 10.37 11. SUPERCONDUCTIVITY 11.1 11.1
INTRODUCTION 11.1 11.2 SUPERCONDUCTING SYSTEMS 11.2 11.3 HIGH
TEMPERATURE SUPERCONDUCTORS 11.4 11.4 ISOTOPE EFFECT 11.5 11.5 CRITICAL
MAGNETIC FIELD 11.6 11.6 MEISSNER EFFECT 11-6 11.7 SUPERCONDUCTORS
COMPARED WITH A PERFECT CONDUCTOR 11.6 11.8 SPECIFICHEAT 11.8 11.9
ENERGY GAP 11.9 11.10 THERMODYNAMICS OF A SUPERCONDUCTOR 11.10 11.11
LONDON THEORY 11.13 11.12 PIPPARD S EQUATION AND COHERENCE LENGTH 11.14
11.13 CLASSIFICATION OF SUPERCONDUCTORS 11.16 11.14 THE MIXED STATE
11.18 11.15 THEORY OF SUPERCONDUCTIVITY (QUALITATIVE IDEAS) 11.19 11.16
FLUX QUANTISATION 11-23 11.17 JOSEPHSON JUNCTION AND JOSEPHSON EFFECT
11.24 11.18 SOME PRACTICAL JOSEPHSON JUNCTIONS 11 -24 11.19 DC JOSEPHSON
EFFECT (JOSEPHSON JUNCTION S WORKING PRINCIPLE) 11.26 11.20 AC JOSEPHSON
EFFECT 11.28 11.21 SQUIDS 11.30 11.22 DC SQUID (A SUPERCONDUCTING LOOP
WITH TWO JOSEPHSON JUNCTIONS) 11.31 11.23 METHOD OF PREPARATION FOR HIGH
T C SUPERCONDUCTORS 11.34 11.24 PROPERTIES OF HIGH TEMPERATURE
SUPERCONDUCTORS 11.35 11.25 APPLICATIONS OF SUPERCONDUCTIVITY 11.36 XX
CONTENTS 11.26 SUPERCONDUCTING MAGNETS 11.37 11.27 APPLICATIONS OF HIGH
T C OXIDE SUPERCONDUCTORS 11.37 11.28 CHALLENGES AND POSSIBILITIES FOR
APPLICATIONS OF USING HIGH T C MATERIALS 11.38 11.29 STRUCTURE OF HIGH T
C CUPRATE SUPERCONDUCTOR MATERIALS 11.38 12. INTERACTION OF ATOMS WITH
EXTERNAL FIELDS AND RADIATION 12.1 12.1 NORMAL ZEEMAN EFFECT 12.1 12.2
ANOMALOUS ZEEMAN EFFECT 12.3 12.3 PASCHEN BACK EFFECT 12.5 12.4 STARK
EFFECT 12.8 12.5 SCATTERINGOFLIGHT 12.10 12.6 LASER 12.15 12.7 PRINCIPLE
OF LASER 12.18 12.8 METHODS OFACHIEVING POPULATION INVERSION 12.19 12.9
THE LASER CAVITY 12.20 12.10 RUBY LASER 12.21 12.11 HELIUM - NEON LASER
12.22 12.12 SEMICONDUCTOR LASER 12.23 12.13 APPLICATIONS OF LASERS 12.25
13. NUCLEARPHYSICS 13.1 13.1 STRUCTURE OF NUCLEI AND NUCLEAR
CONSTITUENTS 13.1 13.2 DISCOVERY OF NEUTRON 13.2 13.3 PROTON-NEUTRON
THEORY 13.4 13.4 TYPES OF NUCLEI 13.4 13.5 NUCLEAR SIZE 13.5 13.6
DEPENDENCE OF THE NUCLEAR RADUE ON THE MASS NUMBER 13.6 13.7 NUCLEAR RADUE
AND QUADRUPOLE MOMENT 13.6 13.8 ATOMIC MASS UNIT, MASS DEFECT AND
NUCLEAR BINDING ENERGY 13.8 13.9 LIQUID DROP MODEL OF THE NUCLEUS 13.9
13.10 WEIZSAECKER SEMI-EMPIRICAL MASS FORMULA 13.10 13.11 NUCLEAR
STABILITY 13.14 13.12 PACKING FRACTION 13.15 13.13 SEPARATION ENERGY
OFTHE LASTNUCLEON 13.17 13.14 EQUATION OF MASS PARABOLAS FOR ISOBARIC
NUCLEI 13.17 13.15 EXAMPLES OF MASS PARABOLAS FOR ISOBARIC NUCLEI 13.20
13.16 THE NUCLEUS*A CLASSICAL OR A QUANTUM SYSTEM? 13.21 13.17 QUANTUM
PROPERTIES OF NUCLEI 13.22 13.18 MIRRORNUCLEI 13.26 CONTENTS XXI 13.19
COULOMB ENERGIES OF MIRROR NUCLEI 13.27 13.20 NUCLEAR FORCE 13.28 13.21
TWO NUCLEON PROBLEM 13.35 13.22 SHELL MODEL OF THE NUCLEUS 13.88 13.23
COLLECTIVE MODEL OF THE NUCLEUS 13.42 14. RADIOACTIVITY AND NUCLEAR
REACTIONS 14.1 14.1 NATURAL RADIOACTIVITY 14.1 14.2 PROPERTIES OF
RADIOACTIVE RADIATIONS 14.3 14.3 NUCLEAR-DECAY 14.4 14.4 LAWS OF
RADIOACTIVE DECAY 14.5 14.5 RADIOACTIVE EQUILIBRIUM 14.9 14.6
RADIOACTIVE DATING (CARBON DATING) 14.13 14.7 RADIOACTIVE SERIES 14.14
14.8 BETA RAY SPECTRA AND NEUTRINO HYPOTHESIS 14.16 14.9 NUCLEAR
REACTIONS 14.17 14.10 COMPOUND NUCLEUS HYPOTHESIS 14.18 14.11 KINETIC
ENERGY OF THE PROJECTILE REQUIRED FOR NUCLEAR REACTION 14.18 14.12
CONSERVATION LAWS IN NUCLEAR REACTIONS 14.18 14.13 0VALUEOFA NUCLEAR
REACTION 14.19 14.14 THEOEEQUATION 14.20 14.15 SOLUTIONOFTHEGEQUATION
14.21 14.16 ARTIFICIAL NUCLEAR TRANSMUTATION 14.26 14.17 CROSS-SECTION
OF NUCLEAR REACTIONS 14.29 14.18 CONCEPT OF SCATTERING CROSS SECUEON
14.31 15. NUCLEAR FISSION AND FUSION 15.1 15.1 DISCOVERY OF NUCLEAR
FISSION 15.1 15.2 ENERGY RELEASED IN FISSION 15.2 15.3 CHAIN REACTION
15.3 15.4 FISSION PRODUCTS IN NUCLEAR FISSION 15.4 15.5 THEORY OF
NUCLEAR FISSION ON THE BASIS OF LIQUID DROP MODEL 15.5 15.6 ENERGY IN
SPONTANEOUS FISSION 15.7 15.7 CRITICAL ASSEMBLY 15.9 15.8 NUCLEAR
REACTOR 15.9 15.9 PARTS OF A NUCLEAR REACTOR 15.10 15.10 NATURAL URANIUM
REACTORS 15.11 15.11 BREEDER REACTOR 15.12 15.12 POWER REACTORS 15.13
15.13 NEUTRON CYCLE IN A THERMAL NUCLEAR REACTOR (THE FOUR FACTOR
FORMULA) 15.13 XX II CONTENTS 15.14 DELAYED NEUTRONS 15.16 15.15 ATOM
BOMB 15.16 15.16 NUCLCAR FUSION 15.17 15.17 SALIENT FEATURES OF THE
FUSION PROCESS 15.18 15.18 NUCLEAR REACTION RATE 15.20 15.19 LAWSON
CRITERION 15.22 15.20 CONDITIONS FOR THERMONUCLEAR REACTION 15.22 15.21
HEATING OF PLASMA 15.23 15.22 CONFINEMENT OF PLASMA 15.23 16.
ACCELERATORS AND DETECTORS OF ELEMENTARY PARTICIES 16.1 16.1 TYPES
OFPARTICLE DETECTORS * 16.1 16.2 GAS FILLED IONIZATION 16.2 16.3 TRACK
DETECTORS 16.14 16.4 NEED FOR ACCELERATION OF CHARGED PARTICIES 16.20
16.5 THE BASIC MECHANISM OF ACCELERATION 16.21 16.6 TYPES OF PARTICLE
ACCELERATORS 16.22 17. THE UNIVERSE 17.1 17.1 INTRODUCTION 17.1 17.2
GALAXY 17.2 17.3 OUR GALAXY (THE MILKY WAY) 17.3 17.4 STARCLUSTERS 17.4
17.5 THE COMPOSITION OF STARS AND GALAXIES 17.4 17.6 CLASSIFICATION OF
STARS ACCORDING TO THEIR SPECTRA 17.4 17.7 HERTZSPRUNG-RUSSELL DIAGRAM
17.5 17.8 STRUCTURE OF THE SUN 17.6 17.9 TEMPERATUREOFTHE SUN 17.8 17.10
SURFACE PHENOMENA ON THE SUN (SUN SPOTS AND SOLAR ACTIVITY) 17.8 17.11
THE EARTH-MOON SYSTEM 17.9 17.12 COMPOSITION OF EARTH S INTERNAL SHELLS
AND EARTH S MAGNETIC FIELD 17.10 17.13 VAN ALLEN S RADIATION BELTS 17.14
17.14 AURORAE 17.15 17.15 EARTH S MAGNETOSPHERE 17.15 17.16 STELLAR
ENERGY (CARBON CYCLE) 17.16 17.17 PROTON-PROTON CYCLE 17.18 17.18
STELLAR EVOLUTION 17.19 17.19 WHITE DWARFS AND BLACK DWARFS 17.22 17.20
CHANDRASEKHAR LIMIT 17.22 CONTENTS XXUEI 17.21 NEUTRON STARS 17.28 17.22
RADIO SOURCES 17.28 17.23 QUASARS 17.29 17.24 PULSARS 17.30 17.25 BLACK
HOLES 17.30 17.26 THE EXPANDING UNIVERSE,, 17.31 17.27 THE ORIGIN OF THE
UNIVERSE (BIG BANG THEORY) 17.32 17.28 HOYLE-NARLIKAR S THEORY OF
GRAVITY (BASIC IDEA) 17.35 17.29 CURVATURE OF SPACE-TIME MANIFOLD 17.36
17.30 THE SOLAR NEUTRINO PUZZLE 17.37 18. ELEMENTARY PARTICLES 18.1 18.1
DISCOVERY OF ELEMENTARY PARTICLES 18.1 18.2 CLASSIFICATION OF ELEMENTARY
PARTICLES 18.2 18.3 STRANGE PARTICLES 18.6 18.4 QUANTUM NUMBERS OF
ELEMENTARY PARTICLES 18.8 18.5 THE X-6 PUZZLE 18.16 18.6 PARTICLES,
ANTIPARTICLES AND ANTIMATTER 18.18 18.7 UNITARY SYMMETRY 18.21 18.8
UNITARY TRANSFORMATION INDUCCD BY A ROTATION 18.21 18.9 THE ISOSPIN
INVARIANCE, THE SU (2) GROUP AND UNITARY SYMMETRY 18.23 18.10 WEIGHT
DIAGRAMS 18.24 18.11 SU(3)GROUPS 18.25 18.12 SU (3) MULTIPLETS 18.27
18.13 BUILDING UP OF THE SUPERMULTIPLETS FROM THE THREE QUARKS 18.29
18.14 THE EIGHTFOLD WAY AND THE QUARK MODEL 18.30 18.15 GLUONS 18.36
18.16 STANDARD MODEL OF PARTICLE PHYSICS 18.37 18.17 SYMMETRIES AND
CONSERVATION LAWS 18.39 18.18 VIOLATION OF C INVARIANCE 18.45 18.19 C-P
VIOLATION IN NEUTRAL K-MESON DECAYS 18.45 18.20 THE C-P-T THEOREM 18.46
18.21 RESONANCE PARTICLES 18.47 18.22 FUNDAMENTAL INTERACTIONS IN NATURE
18.48 18.23 NATURE OF FUNDAMENTAL INTERACTIONS 18.49 18.24 UNIFICATION
OF FUNDAMENTAL FORCES 18.53 18.25 DISCOVERY OFQ-HYPERON 18.55 18.26
QUARK CONTENT OF MESONS AND BARYONS 18.56 XXIV CONTENTS 18.27 PLANCK S
UNITS: (THE UNITS OF FUNDAMENTAL LMPORTANCE IN PHYSICS) 18.57 18.28
PARITY VIOLATION AND CP INVARIANCE IN THE BETA-DECAY OF COBALT - 60
NUCLEUS 18.59 18.29 CP - VIOLATION AND CPT SYMMETRY IN NEUTRAL K - MESON
DECAYS 18.60 19. COSMIC RAYS 19.1 19.1 DISCOVERY AND DETECTION OF COSMIC
RAYS 19.1 19.2 THE ORIGIN AND PROPAGATION OF COSMIC RAYS 19.1 19.3
PRIMARY COSMIC RAYS 19.2 19.4 THE SECONDARY RADIATION 19.2 APPENDICES
A.1 1. PREFIXES AND GREEK SYMBOLS A.3 2. PHYSICAL CONSTANTS WITH THEIR
VALUCS IN SI UNITS A.5 3. UNITS OF MEASUREMENT A.7 4. SPIN MAGNETIC
MOMENT AND PAULI SPIN MATRICES A.12 5. DIRAC DELTA FUNCTION A.14 6.
MAJOR FACTS ABOUT THC EARTH AND EARTH S ATMOSPHERE A. 15 7. AN OVERVIEW
OF GROUP-REPRESENTATIONS AND WEIGHT VECTORS PERCEIVED IN CHAPTER 18 A.17
8. THE SOLAR SYSTEM A.20 9. AN ELECTRON MICROSCOPE A.22 10. THE QUANTUM
PARTICLES (BOSONS AND FERMIONS) A.24 11. DIRAC NOTATIONS IN QUANTUM
MECHANICS A.26 12. SOME CONVERSION FACTORS A.28 13. PHYSICAL DIMENSIONS
OF SOME TYPICAL OBJECTS A.29 14. SOME MATHEMATICAL RELATIONS A.30 15.
BRIEF OUTLINE OF STELLAR EVOLUTION A.33 REFERENCES R. 1 EXERCISES E. 1
INDEX 1.1
|
| any_adam_object | 1 |
| author | Saxena, A. K. |
| author_GND | (DE-588)139684115 |
| author_facet | Saxena, A. K. |
| author_role | aut |
| author_sort | Saxena, A. K. |
| author_variant | a k s ak aks |
| building | Verbundindex |
| bvnumber | BV035292975 |
| callnumber-first | Q - Science |
| callnumber-label | QC21 |
| callnumber-raw | QC21.3 |
| callnumber-search | QC21.3 |
| callnumber-sort | QC 221.3 |
| callnumber-subject | QC - Physics |
| ctrlnum | (OCoLC)180691123 (DE-599)BVBBV035292975 |
| dewey-full | 539 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 539 - Modern physics |
| dewey-raw | 539 |
| dewey-search | 539 |
| dewey-sort | 3539 |
| dewey-tens | 530 - Physics |
| discipline | Physik |
| edition | 2. ed. |
| format | Book |
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| id | DE-604.BV035292975 |
| illustrated | Illustrated |
| indexdate | 2024-07-09T21:30:36Z |
| institution | BVB |
| isbn | 9781842654224 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-017097994 |
| oclc_num | 180691123 |
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| owner | DE-29T |
| owner_facet | DE-29T |
| physical | getr. Zählung graph. Darst. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Alpha Science Internat. |
| record_format | marc |
| spelling | Saxena, A. K. Verfasser (DE-588)139684115 aut Principles of modern physics Ajay K. Saxena 2. ed. Oxford Alpha Science Internat. 2007 getr. Zählung graph. Darst. txt rdacontent n rdamedia nc rdacarrier Physique - Manuels d'enseignement supérieur ram Physics Textbooks Moderne Physik (DE-588)4711780-1 gnd rswk-swf 1\p (DE-588)4123623-3 Lehrbuch gnd-content Moderne Physik (DE-588)4711780-1 s DE-604 OEBV Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017097994&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Saxena, A. K. Principles of modern physics Physique - Manuels d'enseignement supérieur ram Physics Textbooks Moderne Physik (DE-588)4711780-1 gnd |
| subject_GND | (DE-588)4711780-1 (DE-588)4123623-3 |
| title | Principles of modern physics |
| title_auth | Principles of modern physics |
| title_exact_search | Principles of modern physics |
| title_full | Principles of modern physics Ajay K. Saxena |
| title_fullStr | Principles of modern physics Ajay K. Saxena |
| title_full_unstemmed | Principles of modern physics Ajay K. Saxena |
| title_short | Principles of modern physics |
| title_sort | principles of modern physics |
| topic | Physique - Manuels d'enseignement supérieur ram Physics Textbooks Moderne Physik (DE-588)4711780-1 gnd |
| topic_facet | Physique - Manuels d'enseignement supérieur Physics Textbooks Moderne Physik Lehrbuch |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017097994&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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