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This new edition of the unrivalled textbook introduces the fundamental concepts of quantum mechanics such as waves, particles and probability before explaining the postulates of quantum mechanics in detail. In the proven didactic manner, the textbook then covers the classical scope of introductory quantum mechanics, namely simple two-level systems, the one-dimensional harmonic oscillator, the quantized angular momentum and particles in a central potential.
The entire book has been revised to take into account new developments in quantum mechanics curricula. The textbook retains its typical style also in the new edition: it explains the fundamental concepts in chapters which are elaborated in accompanying complements that provide more detailed discussions, examples and applications. * The quantum mechanics classic in a new edition: written by 1997 Nobel laureate Claude Cohen-Tannoudji and his colleagues Bernard Diu and Franck Laloe * As easily comprehensible as possible: all steps of the physical background and its mathematical representation are spelled out explicitly * Comprehensive: in addition to the fundamentals themselves, the book contains more than 350 worked examples plus exercises Claude Cohen-Tannoudji was a researcher at the Kastler-Brossel laboratory of the Ecole Normale Superieure in Paris where he also studied and received his PhD in 1962.
In 1973 he became Professor of atomic and molecular physics at the College des France. His main research interests were optical pumping, quantum optics and atom-photon interactions. In 1997, Claude Cohen-Tannoudji, together with Steven Chu and William D. Phillips, was awarded the Nobel Prize in Physics for his research on laser cooling and trapping of neutral atoms. Bernard Diu was Professor at the Denis Diderot University (Paris VII).
He was engaged in research at the Laboratory of Theoretical Physics and High Energy where his focus was on strong interactions physics and statistical mechanics. Franck Laloe was a researcher at the Kastler-Brossel laboratory of the Ecole Normale Superieure in Paris. His first assignment was with the University of Paris VI before he was appointed to the CNRS, the French National Research Center. His research was focused on optical pumping, statistical mechanics of quantum gases, musical acoustics and the foundations of quantum mechanics.
Annað
- Höfundar: Claude Cohen-Tannoudji, Bernard Diu, Franck Laloë
- Útgáfa:2
- Útgáfudagur: 11-06-2020
- Hægt að prenta út 10 bls.
- Hægt að afrita 2 bls.
- Format:ePub
- ISBN 13: 9783527822713
- Print ISBN: 9783527345533
- ISBN 10: 3527822712
Efnisyfirlit
- Cover
- Foreword
- Acknowledgments
- Chapter I: Waves and particles. Introduction to the fundamental ideas of quantum mechanics
- A. Electromagnetic waves and photons
- B. Material particles and matter waves
- C. Quantum description of a particle. Wave packets
- D. Particle in a time-independent scalar potential
- COMPLEMENTS OF CHAPTER I, READER’S GUIDE
- Complement AI Order of magnitude of the wavelengths associated with material particles
- Complement BI Constraints imposed by the uncertainty relations
- 1. Macroscopic system
- 2. Microscopic system
- Complement CI Heisenberg relation and atomic parameters
- Complement DI An experiment illustrating the Heisenberg relations
- Complement EI A simple treatment of a two-dimensional wave packet
- 1. Introduction
- 2. Angular dispersion and lateral dimensions
- 3. Discussion
- Complement FI The relationship between one- and three-dimensional problems
- 1. Three-dimensional wave packet
- 2. Justification of one-dimensional models
- Complement GI One-dimensional Gaussian wave packet: spreading of the wave packet
- 1. Definition of a Gaussian wave packet
- 2. Calculation of ∆x and ∆p; uncertainty relation
- 3. Evolution of the wave packet
- Complement HI Stationary states of a particle in one-dimensional square potentials
- 1. Behavior of a stationary wave function φ(x)
- 2. Some simple cases
- Complement JI Behavior of a wave packet at a potential step
- 1. Total reflection: E < V0
- 2. Partial reflection: E > V0
- Complement KI
- Exercises
- 2. Bound state of a particle in a “delta function potential”
- 3. Transmission of a “delta function” potential barrier
- 4. Return to exercise 2, using this time the Fourier transform.
- 5. Well consisting of two delta functions
- A. Space of the one-particle wave function
- B. State space. Dirac notation
- C. Representations in state space
- D. Eigenvalue equations. Observables
- E. Two important examples of representations and observables
- F. Tensor product of state spaces11
- COMPLEMENTS OF CHAPTER II, , READER’S GUIDE
- Complement AII The Schwarz inequality
- Complement BII Review of some useful properties of linear operators
- 1. Trace of an operator
- 2. Commutator algebra
- 3. Restriction of an operator to a subspace
- 4. Functions of operators
- 5. Derivative of an operator
- Complement CII Unitary operators
- 1. General properties of unitary operators
- 2. Unitary transformations of operators
- 3. The infinitesimal unitary operator
- Complement DII A more detailed study of the { |r〉 }and { |P〉 } representations
- 1. The { |r〉 } representation
- 2. The { |P〉 } representation
- Complement EII Some general properties of two observables, Q and P, whose commutator is equal to
- 1. The operator S(λ): definition, properties
- 2. Eigenvalues and eigenvectors of Q
- 3. The q representation
- 4. The representation. The symmetric nature of the P and Q observables
- Complement FII The parity operator
- 1. The parity operator
- 2. Even and odd operators
- 4. Application to an important special case
- Complement GII An application of the properties of the tensor product: the two-dimensional infinite well
- 1. Definition; eigenstates
- 2. Study of the energy levels
- Complement HII Exercises
- Dirac notation. Commutators. Eigenvectors and eigenvalues
- Complete sets of commuting observables, C.S.C.O.
- Solution of exercise 11
- Solution of exercise 12
- A. Introduction
- B. Statement of the postulates
- C. The physical interpretation of the postulates concerning observables and their measurement
- D. The physical implications of the Schrödinger equation
- E. The superposition principle and physical predictions
- COMPLEMENTS OF CHAPTER III, READER’S GUIDE
- Complement AIII Particle in an infinite potential well
- 1. Distribution of the momentum values in a stationary state
- 2. Evolution of the particle’s wave function
- 3. Perturbation created by a position measurement
- Complement BIII Study of the probability current in some special cases
- 1. Expression for the current in constant potential regions
- 2. Application to potential step problems
- 3. Probability current of incident and evanescent waves, in the case of reflection from a two-dimensional potential step
- Complement CIII Root mean square deviations of two conjugate observables
- 1. The Heisenberg relation for P and Q
- 2. The “minimum” wave packet
- Complement DIII Measurements bearing on only one part of a physical system
- 1. Calculation of the physical predictions
- 2. Physical meaning of a tensor product state
- 3. Physical meaning of a state that is not a tensor product
- Complement EIII The density operator
- 1. Outline of the problem
- 2. The concept of a statistical mixture of states
- 3. The pure case. Introduction of the density operator
- 4. A statistical mixture of states (non-pure case)
- 5. Use of the density operator: some applications
- Complement FIII The evolution operator
- 1. General properties
- 2. Case of conservative systems
- Complement GIII The Schrödinger and Heisenberg pictures
- Complement HIII Gauge invariance
- 1. Outline of the problem: scalar and vector potentials associated with an electromagnetic field; concept of a gauge
- 2. Gauge invariance in classical mechanics
- 3. Gauge invariance in quantum mechanics
- Complement JIII Propagator for the Schrödinger equation
- 1. Introduction
- 2. Existence and properties of a propagator K(2, 1)
- 3. Lagrangian formulation of quantum mechanics
- Complement KIII Unstable states. Lifetime
- 1. Introduction
- 2. Definition of the lifetime
- 3. Phenomenological description of the instability of a state
- Complement LIII Exercises
- Complement MIII Bound states in a “potential well” of arbitrary shape
- 1. Quantization of the bound state energies
- 2. Minimum value of the ground state energy
- Complement NIII Unbound states of a particle in the presence of a potential well or barrier of arbitrary shape
- 1. Transmission matrix M(k)
- 2. Transmission and reflection coefficients
- 3. Example
- Complement OIII Quantum properties of a particle in a one-dimensional periodic structure
- 1. Passage through several successive identical potential barriers
- 2. Discussion: the concept of an allowed or forbidden energy band
- 3. Quantization of energy levels in a periodic potential; effect of boundary conditions
- A. Spin 1/2 particle: quantization of the angular momentum
- B. Illustration of the postulates in the case of a spin 1/2
- C. General study of two-level systems
- COMPLEMENTS OF CHAPTER IV, READER’S GUIDE
- Complement AIV The Pauli matrices
- 1. Definition; eigenvalues and eigenvectors
- 2. Simple properties
- 3. A convenient basis of the 2 2 matrix space
- Complement BIV Diagonalization of a 2 2 Hermitian matrix
- 1. Introduction
- 2. Changing the eigenvalue origin
- 3. Calculation of the eigenvalues and eigenvectors
- Complement CIV Fictitious spin 1/2 associated with a two-level system
- 1. Introduction
- 2. Interpretation of the Hamiltonian in terms of fictitious spin
- 3. Geometrical interpretation of the various effects discussed in § C of Chapter IV
- Complement DIV System of two spin 1/2 particles
- 1. Quantum mechanical description
- 2. Prediction of the measurement results
- Complement EIV Spin 1 2 density matrix
- 1. Introduction
- 2. Density matrix of a perfectly polarized spin (pure case)
- 3. Example of a statistical mixture: unpolarized spin
- 4. Spin 1/2 at thermodynamic equilibrium in a static field
- 5. Expansion of the density matrix in terms of the Pauli matrices
- Complement FIV Spin 1/2 particle in a static and a rotating magnetic fields: magnetic resonance
- 1. Classical treatment; rotating reference frame
- 2. Quantum mechanical treatment
- 3. Relation between the classical treatment and the quantum mechanical treatment: evolution of M
- 4. Bloch equations
- Complement GIV A simple model of the ammonia molecule
- 1. Description of the model
- 2. Eigenfunctions and eigenvalues of the Hamiltonian
- 3. The ammonia molecule considered as a two-level system
- Complement HIV Effects of a coupling between a stable state and an unstable state
- 1. Introduction. Notation
- 2. Influence of a weak coupling on states of different energies
- 3. Influence of an arbitrary coupling on states of the same energy
- A. Introduction
- B. Eigenvalues of the Hamiltonian
- C. Eigenstates of the Hamiltonian
- D. Discussion
- Complement AV Some examples of harmonic oscillators
- 1. Vibration of the nuclei of a diatomic molecule
- 2. Vibration of the nuclei in a crystal
- 3. Torsional oscillations of a molecule: ethylene
- 4. Heavy muonic atoms
- Complement BV Study of the stationary states in the representation. Hermite polynomials
- 1. Hermite polynomials
- 2. The eigenfunctions of the harmonic oscillator Hamiltonian
- Complement CV Solving the eigenvalue equation of the harmonic oscillator by the polynomial method
- 1. Changing the function and the variable
- 2. The polynomial method
- Complement DV Study of the stationary states in the representation
- 1. Wave functions in momentum space
- 2. Discussion
- Complement EV The isotropic three-dimensional harmonic oscillator
- 1. The Hamiltonian operator
- 2. Separation of the variables in Cartesian coordinates
- 3. Degeneracy of the energy levels
- Complement FV A charged harmonic oscillator in a uniform electric field
- 1. Eigenvalue equation of in the representation
- 2. Discussion
- 3. Use of the translation operator
- Complement GV Coherent “quasi-classical” states of the harmonic oscillator
- 1. Quasi-classical states
- 2. Properties of the states
- 3. Time evolution of a quasi-classical state
- 4. Example: quantum mechanical treatment of a macroscopic oscillator
- Complement HV Normal vibrational modes of two coupled harmonic oscillators
- 1. Vibration of the two coupled in classical mechanics
- 2. Vibrational states of the system in quantum mechanics
- Complement JV Vibrational modes of an infinite linear chain of coupled harmonic oscillators; phonons
- 1. Classical treatment
- 2. Quantum mechanical treatment
- 3. Application to the study of crystal vibrations: phonons
- Complement KV Vibrational modes of a continuous physical system. Application to radiation; photons
- 1. Outline of the problem
- 2. Vibrational modes of a continuous mechanical system: example of a vibrating string
- 3. Vibrational modes of radiation: photons
- Complement LV One-dimensional harmonic oscillator in thermodynamic equilibrium at a temperature T
- 1. Mean value of the energy
- 2. Discussion
- 3. Applications
- 4. Probability distribution of the observable X
- Complement MV Exercises
- A. Introduction: the importance of angular momentum
- B. Commutation relations characteristic of angular momentum
- C. General theory of angular momentum
- D. Application to orbital angular momentum
- Complement AVI Spherical harmonics
- 1. Calculation of spherical harmonics
- 2. Properties of spherical harmonics
- Complement BVI Angular momentum and rotations
- 1. Introduction
- 2. Brief study of geometrical rotations
- 3. Rotation operators in state space. Example: a spinless particle
- 4. Rotation operators in the state space of an arbitrary system
- 5. Rotation of observables
- 6. Rotation invariance
- Complement CVI Rotation of diatomic molecules
- 1. Introduction
- 2. Rigid rotator. Classical study
- 3. Quantization of the rigid rotator
- 4. Experimental evidence for the rotation of molecules
- Complement DVI Angular momentum of stationary states of a two-dimensional harmonic oscillator
- 1. Introduction
- 2. Classification of the stationary states by the quantum numbers nx and ny
- 3. Classification of the stationary states in terms of their angular momenta
- 4. Quasi-classical states
- Complement EVI A charged particle in a magnetic field: Landau levels
- 1. Review of the classical problem
- 2. General quantum mechanical properties of a particle in a magnetic field
- 3. Case of a uniform magnetic field
- A. Stationary states of a particle in a central potential
- B. Motion of the center of mass and relative motion for a system of two interacting particles
- C. The hydrogen atom
- COMPLEMENTS OF CHAPTER VII, READER’S GUIDE
- Complement AVII Hydrogen-like systems
- 1. Hydrogen-like systems with one electron
- 2. Hydrogen-like systems without an electron
- Complement BVII A soluble example of a central potential: the isotropic three-dimensional harmonic oscillator
- 1. Solving the radial equation
- 2. Energy levels and stationary wave functions
- Complement CVII Probability currents associated with the stationary states of the hydrogen atom
- 1. General expression for the probability current
- 2. Application to the stationary states of the hydrogen atom
- Complement DVII The hydrogen atom placed in a uniform magnetic field. Paramagnetism and diamagnetism. The Zeeman effect
- 1. The Hamiltonian of the problem. The paramagnetic term and the diamagnetic term
- 2. The Zeeman effect
- Complement EVII Some atomic orbitals. Hybrid orbitals
- 1. Introduction
- 2. Atomic orbitals associated with real wave functions
- 3. sp hybridization
- 4. sp2 hybridization
- 5. sp3 hybridization
- Complement FVII Vibrational-rotational levels of diatomic molecules
- 1. Introduction
- 2. Approximate solution of the radial equation
- 3. Evaluation of some corrections
- Complement GVII Exercises
- 1. Particle in a cylindrically symmetric potential
- 2. Three-dimensional harmonic oscillator in a uniform magnetic field
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