viⅷi Contents Problems 399 Further reading 11 Hydrogen and helium atoms 401 11.1 Introduction 401 11.2 Quantum theory of the hydrogen atom 403 113 Atom and magnetic field 413 11.4 Relativistic corrections 11.5 Helium atom 11.6 Many-electron effect Summary Problems 437 Further reading 438 12 Hydrogen molecular ion 439 12.1 The molecular problem 439 12.2 Born-Oppenheimer approximation 440 12.3 Vibrational and rotational degrees of freedom 12.4 The Morse potential 12.5 Chemical bonds and further approximations 44g Summary Problems Further reading 454 13 Quantum optics 13.1 Quantization of the electromagnetic field 57 13.2 Thermodynamic equilibrium of the radiation field 462 133 Phase mber ertainty relation 13.4 Special states of the electromagnetic field 465 13.5 Quasi-probability distributions 13.6 Quantum-optical coherence 481 13.7 Atom-field interaction 13.8 Geometric phase 13.9 The Casimir effect 501 Summary 506 Problems Further reading Part IV Quantum information:state and correlations 14 Quantum theory of open systems 513 14.1 General considerations 514 14.2 The master equation 516
viii Contents Problems 399 Further reading 399 11 Hydrogen and helium atoms 401 11.1 Introduction 401 11.2 Quantum theory of the hydrogen atom 403 11.3 Atom and magnetic field 413 11.4 Relativistic corrections 423 11.5 Helium atom 426 11.6 Many-electron effects 431 Summary 436 Problems 437 Further reading 438 12 Hydrogen molecular ion 439 12.1 The molecular problem 439 12.2 Born–Oppenheimer approximation 440 12.3 Vibrational and rotational degrees of freedom 443 12.4 The Morse potential 447 12.5 Chemical bonds and further approximations 449 Summary 453 Problems 453 Further reading 454 13 Quantum optics 455 13.1 Quantization of the electromagnetic field 457 13.2 Thermodynamic equilibrium of the radiation field 462 13.3 Phase–number uncertainty relation 463 13.4 Special states of the electromagnetic field 465 13.5 Quasi-probability distributions 474 13.6 Quantum-optical coherence 481 13.7 Atom–field interaction 484 13.8 Geometric phase 497 13.9 The Casimir effect 501 Summary 506 Problems 507 Further reading 509 Part IV Quantum information: state and correlations 14 Quantum theory of open systems 513 14.1 General considerations 514 14.2 The master equation 516�
Contents 14.3 A formal generalization 14.4 Quantum jumps and quantum trajectories 14.5 Quantum optics and Schrodinger cats Summary Problems 9 Further reading 542 15 State measurement in quantum mechanics 15.1 Protective measurement of the state 54 15.2 Quantum cloning and unitarity violation 15.3 Measurement and reversibility Quantum state reconstruction 15.5 The nature of quantum states Summary Problem Further reading 16 Entanglement:non-separability 567 16.1 EPR 16.2 Bohm's version of the EPR state 16.3 HV theories 164 Bell's contribution 16.5 Experimental test 16.6 Bell inequalities with homodyne detection 167 Bell theorem without inequalities 16.8 What is quantum non-locality? 16.9 Further developments about inequalities 16.10 Conclusion Summary Problems Further reading 627 17 Entanglement:quantum information and computation Information and entropy 17.2 Entanglement and information 17.3 Measurement and information 17.4 Qubits 17.5 Teleportation 创 17.6 Quantum cryptography 646 17.7 Elements of quantum computation 650 17.8 Quantum algorithms and d error correctior Summary
ix Contents 14.3 A formal generalization 523 14.4 Quantum jumps and quantum trajectories 528 14.5 Quantum optics and Schrödinger cats 533 Summary 540 Problems 541 Further reading 542 15 State measurement in quantum mechanics 544 15.1 Protective measurement of the state 544 15.2 Quantum cloning and unitarity violation 548 15.3 Measurement and reversibility 550 15.4 Quantum state reconstruction 554 15.5 The nature of quantum states 564 Summary 565 Problems 565 Further reading 566 16 Entanglement: non-separability 567 16.1 EPR 568 16.2 Bohm’s version of the EPR state 573 16.3 HV theories 577 16.4 Bell’s contribution 582 16.5 Experimental tests 595 16.6 Bell inequalities with homodyne detection 605 16.7 Bell theorem without inequalities 613 16.8 What is quantum non-locality? 619 16.9 Further developments about inequalities 623 16.10 Conclusion 625 Summary 625 Problems 626 Further reading 627 17 Entanglement: quantum information and computation 628 17.1 Information and entropy 628 17.2 Entanglement and information 631 17.3 Measurement and information 639 17.4 Qubits 642 17.5 Teleportation 643 17.6 Quantum cryptography 646 17.7 Elements of quantum computation 650 17.8 Quantum algorithms and error correction 659 Summary 671�
Contents Problems 672 Further reading 673 Bibliography 674 Author index 710 Subject index 716
x Contents Problems 672 Further reading 673 Bibliography 674 Author index 710 Subject index 716�
Figures 1.1 Graphical representation of the Liouville theorem page 12 1.2 Photoelectric effect 13 1.3 Mach-Zender interferometer 15 1.4 The Michelson-Morley interferometer 16 1.5 Interferometer for detecting gravitational waves 17 1.6 Interference in the Mach-Zender interferometer 17 1.7 Results of the experiment performed by Grangier,Roger,and Aspect 18 1.8 Oscillation of electric and magnetic fields 20 1.9 Polarization of classical light 21 1.10 Decomposition of an arbitrary vector la) 22 1.11 Poincare sphere representation of states 28 1.12 Mach-Zender interferometer with the lower path blocked by the screen S 30 1.13 Black-body radiation intensity corresponding to the formula of Rayleigh- Jeans (1),Planck (2),and Wien (3) 32 1.14 Planck's radiation curves in logarithmic scale for the temperatures of liquid nitrogen,melting ice,boiling water,melting aluminium,and the solar surface 33 1.15 Compton effect 34 1.16 Dulong-Petit's,Einstein's,and Debye's predictions for specific heat 36 1.17 Lyman series for ionized helium 37 1.18 The Stern-Gerlach Experiment 39 1.19 Momentum conservation in the Compton effect 41 2.1 Polarization beam splitter 44 2.2 Change of basis 52 2.3 Filters 62 2.4 Two sequences of two rotations of a book 65 2.5 Probability distributions of position and momentum for a momentum eigenfunction 85 2.6 Probability distributions of position and momentum for a position eigenfunction 86 2.7 Time evolution of a classical degree of freedom in phase space and graphical representation of the uncertainty relation 88 2.8 Inverse proportionality between momentum and position uncertainties 89 2.9 Smooth complementarity between wave and particle 90 2.10 Illustration of the distributive law 93 2.11 Proposed interferometry and resulting non-Boolean algebra and Boolean subalgebras 94
Figures 1.1 Graphical representation of the Liouville theorem page 12 1.2 Photoelectric effect 13 1.3 Mach–Zender interferometer 15 1.4 The Michelson–Morley interferometer 16 1.5 Interferometer for detecting gravitational waves 17 1.6 Interference in the Mach–Zender interferometer 17 1.7 Results of the experiment performed by Grangier, Roger, and Aspect 18 1.8 Oscillation of electric and magnetic fields 20 1.9 Polarization of classical light 21 1.10 Decomposition of an arbitrary vector |a 22 1.11 Poincaré sphere representation of states 28 1.12 Mach–Zender interferometer with the lower path blocked by the screen S 30 1.13 Black-body radiation intensity corresponding to the formula of Rayleigh– Jeans (1), Planck (2), and Wien (3) 32 1.14 Planck’s radiation curves in logarithmic scale for the temperatures of liquid nitrogen, melting ice, boiling water, melting aluminium, and the solar surface 33 1.15 Compton effect 34 1.16 Dulong–Petit’s, Einstein’s, and Debye’s predictions for specific heat 36 1.17 Lyman series for ionized helium 37 1.18 The Stern–Gerlach Experiment 39 1.19 Momentum conservation in the Compton effect 41 2.1 Polarization beam splitter 44 2.2 Change of basis 52 2.3 Filters 62 2.4 Two sequences of two rotations of a book 65 2.5 Probability distributions of position and momentum for a momentum eigenfunction 85 2.6 Probability distributions of position and momentum for a position eigenfunction 86 2.7 Time evolution of a classical degree of freedom in phase space and graphical representation of the uncertainty relation 88 2.8 Inverse proportionality between momentum and position uncertainties 89 2.9 Smooth complementarity between wave and particle 90 2.10 Illustration of the distributive law 93 2.11 Proposed interferometry and resulting non-Boolean algebra and Boolean subalgebras 94�
Figures 2.12 hasse diagrams of several boolean and non-Boolean algebras 3.1 Positive potential vanishing at infinity Potential function tending to finite values asx →士 0 Potential well 111 3.4 Relation between two different inertial reference frames R and R'under Galilei transformations 3 3.5 Particle in a box of dimensiona Energy levels of a particle in a one-dimensional box 3.7 First three energy eigenfunctions for a one-dimensional particle confined in a box of dimension a 115 3.8 Beam Splitters as unitary operators 119 3.9 proiector as a residue of the closed contour in a complex plane 124 3.10 A graphical representation of the apparatus proposed by Bohr 4.1 Schematic and tric one-dir otential wells 4.2 Solution of Eq.(4.8) 143 4.3 Wave functions and probability densities for the first three eigenfunctions for the symmetric finite-well potential 1 4 Stepwise continuity Potential barrier 64 4.6 Closed surface used to compute the flux of J 4 Delta potential barrier 149 4.8 Classical tuming points and quantum tunneling 4. Tunneling of o-particles 4.10 Carbon atoms shown by scanning tunneling microscopy 153 411 Potential and energy levels of the harmonic oscillator 4.12 Eigenfunctions for the one-dimensional harmonic oscillator 162 4.13 Potential energy corresponding to a particle in a uniform field 1 4.14 Triangular well 167 4.15 A quantum particle with energy E enc ounters a potential step of heigh Vo<E 171 4.16 Rectangular potential barrier with finite width a 171 5 Representation of pure and mixed states on a sphere 187 61 Angular momentum of a classical particle 6. Levi-Civita tensor Relationship between rectangular and spherical coordinates 200 s-and p-states 206 6 Rigid rotato 6.6 Energy levels and transition frequencies for a rigid rotator 67 Cylindrical coordinates 212 Energy levels of the thre -dimensional ha monic oscillator 6.9 Levels in the spectrum of hydrogen atom 6.10 An electric dipole with charges +e and -e in an electric field gradient 218 6.1m Scheme of spin superposition in single-crystal neutron interferometry 223 6.12 Lande vectorial model for angul 227