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100   $a19950424d1996      uy         0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aQuantum mechanics II $ea second course in quantum theory /$fRubin H. Landau
205   $a2nd ed.
210   $aNew York $cWiley$dc1996
215   $a1 online resource (520 p.)
300   $a"A Wiley-Interscience publication."
311 08$a9780471116080 
311 08$a0471116084 
320   $aIncludes bibliographical references (p. [483]-489) and index.
327   $aQUANTUM MECHANICS II; CONTENTS; PART I: SCATTERING AND INTEGRAL QUANTUM MECHANICS; CHAPTER 1 SCATTERING; 1.1 The Scattering Experiment; Time-Dependent Approach; The Time-Independent Trick; 1.2 The 1- and 2-Body Schro?dinger Equations; 1.3 Coordinate Systems and Elastic Scattering; Elastic Kinematics; 1.4 The Particle and Channel Concepts; 1.5 Problems; CHAPTER 2 CURRENTS AND CROSS SECTIONS; 2.1 Elastic Scattering Currents; 2.2 Differential Cross Sections; Nonelastic Cross Sections (Absorption); 2.3 Total Cross Section; 2.4 The Optical Theorem; 2.5 Problems; CHAPTER 3 PARTIAL-WAVE EXPANSIONS
327   $a3.1 Shifted WavesPlane Waves; Distorted Waves; Phase Shifts; Incoming and Outgoing Waves; Elastic Waves with Absorption; 3.2 Partial-Wave Amplitudes; Differential Cross Section; Total Cross Sections; 3.3 Actually Solving Schro?dinger's Equation; Just for Scattering; Bound State Connection; 3.4 Problems; CHAPTER 4 SCATTERING APPLICATIONS: LENGTHS, RESONANCES, COULOMB; 4.1 The Low-Energy Limit; Scattering Length; Low-Energy Wave Function; Relation to Bound States; 4.2 Resonances; Breit-Wigner Resonances; Complex Energy States and Exponential Decay O; 4.3 Coulomb Scattering: A Bad Example
327   $aPure Coulomb ScatteringShielded Coulomb Potential; Coulomb Plus Short-Range Potentials O; 4.4 Problems; CHAPTER 5 GREEN'S FUNCTIONS AND INTEGRAL QUANTUM MECHANICS; 5.1 Definition of Green's Function; 5.2 Solution via Eigenfunction Expansion; 5.3 Solution via Spectral Representation; Evaluation of G with Residues; Other Boundary Conditions; 5.4 Lippmann-Schwinger Wave Equation; Integral Expression for f; 5.5 Born Approximation: The Neumann Series; Yukawa and Coulomb Potentials; 5.6 Scattering from Bound Systems O; 5.7 Problems; CHAPTER 6 TRANSITION AND POTENTIAL MATRICES
327   $a6.1 T- and V-Matrix Elements6.2 Lippmann-Schwinger Equation for T; Easy Derivation of Born Series; 6.3 Off the Energy Shell; Example of Off-Shell T; 6.4 Problems; CHAPTER 7 FORMAL QUANTUM MECHANICS; 7.1 Operator Schro?dinger's Equation; 7.2 Operator Lippmann-Schwinger Equations; Momentum Space LS Wave Equation; Other Operator Forms; Return of the Schro?dinger Equation O; 7.3 Proof of Orthogonality O; 7.4 Operator Equation for T; 7.5 The Bound-State Connection; 7.6 Unitarity of T and the Optical Theorem; 7.7 Reaction and Scattering Matrices; 7.8 The Two-Potential Formula, Tutorial; 7.9 Problems
327   $aCHAPTER 8 THE ANGULAR MOMENTUM BASIS8.1 Partial-Wave Green's Function; 8.2 The Radial Wave Function; 8.3 The T Matrix; 8.4 Energy-Angular Momentum Basis; Completeness Relation; The (k) Expansion; Normalization; Momentum Space Wave Function; The p-Space Wave Functions; Schro?dinger Equation; Momentum Space Wave Function; V and T Matrix Elements; Example: Off-Shell T for Square Well; Born Approximation for Tl; 8.5 Optical Theorem; 8.6 On-Shell Rl and Tl; 8.7 Born Series for Wave Function; 8.8 Problems; CHAPTER 9 SPIN THEORY; 9.1 Basics; Definitions; Mathematical Description; SpinSpace
327   $aJust for Spin One Half
330   $aHere is a readable and intuitive quantum mechanics text that covers scattering theory, relativistic quantum mechanics, and field theory. This expanded and updated Second Edition - with five new chapters - emphasizes the concrete and calculable over the abstract and pure, and helps turn students into researchers without diminishing their sense of wonder at physics and nature.As a one-year graduate-level course, Quantum Mechanics II: A Second Course in Quantum Theory leads from quantum basics to basic field theory, and lays the foundation for research-oriented specialty courses. Used sel
517 3 $aQuantum mechanics 2
517 3 $aQuantum mechanics two
606   $aQuantum theory
606   $aPhysics
615  0$aQuantum theory.
615  0$aPhysics.
676   $a530.12
676   $a620.11
700   $aLandau$b Rubin H$060004
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910144733403321
996   $aQuantum mechanics II$9190154
997   $aUNINA