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940707s1994 nyua b 001 0 eng |
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|a 94026837
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|a 0306447908
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|a (NhCcYBP)YBT 94026837
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|a (NhCcYBP)YBP97281131843
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|a DLC
|c DLC
|d DLC
|d OrLoB-B
|d OCoLC
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050 |
0 |
0 |
|a QC174.12
|b .S52 1994
|
082 |
0 |
0 |
|a 530.1/2
|2 20
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100 |
1 |
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|a Shankar, Ramamurti.
|0 http://id.loc.gov/authorities/names/n79126576
|1 http://viaf.org/viaf/93976547
|
245 |
1 |
0 |
|a Principles of quantum mechanics /
|c R. Shankar.
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250 |
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|a 2nd ed.
|
260 |
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|a New York :
|b Plenum Press,
|c c1994.
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300 |
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|a xviii, 676 p. :
|b ill. ;
|c 27 cm.
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336 |
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|a text
|b txt
|2 rdacontent
|0 http://id.loc.gov/vocabulary/contentTypes/txt
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337 |
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|a unmediated
|b n
|2 rdamedia
|0 http://id.loc.gov/vocabulary/mediaTypes/n
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|a volume
|b nc
|2 rdacarrier
|0 http://id.loc.gov/vocabulary/carriers/nc
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504 |
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|a Includes bibliographical references and index.
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505 |
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0 |
|g 1.
|t Mathematical Introduction.
|g 1.1.
|t Linear Vector Spaces: Basics.
|g 1.2.
|t Inner Product Spaces.
|g 1.3.
|t Dual Spaces and the Dirac Notation.
|g 1.4.
|t Subspaces.
|g 1.5.
|t Linear Operators.
|g 1.6.
|t Matrix Elements of Linear Operators.
|g 1.7.
|t Active and Passive Transformations.
|g 1.8.
|t The Eigenvalue Problem.
|g 1.9.
|t Functions of Operators and Related Concepts.
|g 1.10.
|t Generalization to Infinite Dimensions --
|g 2.
|t Review of Classical Mechanics.
|g 2.1.
|t The Principle of Least Action and Lagrangian Mechanics.
|g 2.2.
|t The Electromagnetic Lagrangian.
|g 2.3.
|t The Two-Body Problem.
|g 2.4.
|t How Smart Is a Particle?
|g 2.5.
|t The Hamiltonian Formalism.
|g 2.6.
|t The Electromagnetic Force in the Hamiltonian Scheme.
|g 2.7.
|t Cyclic Coordinates, Poisson Brackets, and Canonical Transformations.
|g 2.8.
|t Symmetries and Their Consequences --
|g 3.
|t All Is Not Well with Classical Mechanics.
|g 3.1.
|t Particles and Waves in Classical Physics.
|g 3.2.
|t An Experiment with Waves and Particles (Classical).
|g 3.3.
|t The Double-Slit Experiment with Light.
|g 3.4.
|t Matter Waves (de Broglie Waves) --
|g 4.
|t The Postulates - a General Discussion.
|g 4.1.
|t The Postulates.
|g 4.2.
|t Discussion of Postulates I-III.
|g 4.3.
|t The Schrodinger Equation (Dotting Your i's and Crossing your h's) --
|g 5.
|t Simple Problems in One Dimension.
|g 5.1.
|t The Free Particle.
|g 5.2.
|t The Particle in a Box.
|g 5.3.
|t The Continuity Equation for Probability.
|g 5.4.
|t The Single-Step Potential: a Problem in Scattering.
|g 5.5.
|t The Double-Slit Experiment.
|g 5.6.
|t Some Theorems --
|g 6.
|t The Classical Limit --
|g 7.
|t The Harmonic Oscillator.
|g 7.1.
|t Why Study the Harmonic Oscillator?
|g 7.2.
|t Review of the Classical Oscillator.
|g 7.3.
|t Quantization of the Oscillator (Coordinate Basis).
|g 7.4.
|t The Oscillator in the Energy Basis.
|g 7.5.
|t Passage from the Energy Basis to the X Basis --
|g 8.
|t The Path Integral Formulation of Quantum Theory.
|g 8.1.
|t The Path Integral Recipe.
|g 8.2.
|t Analysis of the Recipe.
|g 8.3.
|t An Approximation to U(t) for the Free Particle.
|g 8.4.
|t Path Integral Evaluation of the Free-Particle Propagator.
|g 8.5.
|t Equivalence to the Schrodinger Equation.
|g 8.6.
|t Potentials of the Form V = a + bx + cx[superscript 2] + dx + exx --
|g 9.
|t The Heisenberg Uncertainty Relations.
|g 9.2.
|t Derivation of the Uncertainty Relations.
|g 9.3.
|t The Minimum Uncertainty Packet.
|g 9.4.
|t Applications of the Uncertainty Principle.
|g 9.5.
|t The Energy-Time Uncertainty Relation --
|g 10.
|t Systems with N Degrees of Freedom.
|g 10.1.
|t N Particles in One Dimension.
|g 10.2.
|t More Particles in More Dimensions.
|g 10.3.
|t Identical Particles --
|g 11.
|t Symmetries and Their Consequences --
|g 11.1.
|t Overview.
|g 11.2.
|t Translational Invariance in Quantum Theory.
|g 11.3.
|t Time Translational Invariance.
|g 11.4.
|t Parity Invariance.
|g 11.5.
|t Time-Reversal Symmetry --
|g 12.
|t Rotational Invariance and Angular Momentum.
|g 12.1.
|t Translations in Two Dimensions.
|g 12.2.
|t Rotations in Two Dimensions.
|g 12.3.
|t The Eigenvalue Problem of L[subscript z].
|g 12.4.
|t Angular Momentum in Three Dimensions.
|g 12.5.
|t The Eigenvalue Problem of L[superscript 2] and L[subscript z].
|g 12.6.
|t Solution of Rotationally Invariant Problems --
|g 13.
|t The Hydrogen Atom.
|g 13.1.
|t The Eigenvalue Problem.
|g 13.2.
|t The Degeneracy of the Hydrogen Spectrum.
|g 13.3.
|t Numerical Estimates and Comparison with Experiment.
|g 13.4.
|t Multielectron Atoms and the Periodic Table --
|g 14.
|t Spin.
|g 14.2.
|t What is the Nature of Spin?
|g 14.3.
|t Kinematics of Spin.
|g 14.4.
|t Spin Dynamics.
|g 14.5.
|t Return of Orbital Degrees of Freedom --
|g 15.
|t Addition of Angular Momenta.
|g 15.1.
|t A Simple Example.
|g 15.2.
|t The General Problem.
|g 15.3.
|t Irreducible Tensor Operators.
|g 15.4.
|t Explanation of Some "Accidental" Degeneracies --
|g 16.
|t Variational and WKB Methods.
|g 16.1.
|t The Variational Method.
|g 16.2.
|t The Wentzel-Kramers-Brillouin Method --
|g 17.
|t Time-Independent Perturbation Theory.
|g 17.1.
|t The Formalism.
|g 17.2.
|t Some Examples.
|g 17.3.
|t Degenerate Perturbation Theory --
|g 18.
|t Time-Dependent Perturbation Theory.
|g 18.1.
|t The Problem.
|g 18.2.
|t First-Order Perturbation Theory.
|g 18.3.
|t Higher Orders in Perturbation Theory.
|g 18.4.
|t A General Discussion of Electromagnetic Interactions.
|g 18.5.
|t Interaction of Atoms with Electromagnetic Radiation --
|g 19.
|t Scattering Theory.
|g 19.2.
|t Recapitulation of One-Dimensional Scattering and Overview.
|g 19.3.
|t The Born Approximation (Time-Dependent Description).
|g 19.4.
|t Born Again (The Time-Independent Approximation).
|g 19.5.
|t The Partial Wave Expansion.
|g 19.6.
|t Two-Particle Scattering --
|g 20.
|t The Dirac Equation.
|g 20.1.
|t The Free-Particle Dirac Equation.
|g 20.2.
|t Electromagnetic Interaction of the Dirac Particle.
|g 20.3.
|t More on Relativistic Quantum Mechanics --
|g 21.
|t Path Integrals - II.
|g 21.1.
|t Derivation of the Path Integral.
|g 21.2.
|t Imaginary Time Formalism.
|g 21.3.
|t Spin and Fermion Path Integrals.
|g 21.4.
|t Summary --
|t App. A.1. Matrix Inversion --
|t App. A.2. Gaussian Integrals --
|t App. A.3. Complex Numbers --
|t App. A.4. The i[epsilon] Prescription.
|
650 |
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0 |
|a Quantum theory.
|0 http://id.loc.gov/authorities/subjects/sh85109469
|
650 |
|
7 |
|a Quantum theory.
|2 fast
|0 http://id.worldcat.org/fast/fst01085128
|
901 |
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|a ToCBNA
|
903 |
|
|
|a HeVa
|
035 |
|
|
|a (OCoLC)30811075
|
929 |
|
|
|a cat
|
999 |
f |
f |
|i e3423290-630b-54c3-99f6-b57e0f5e8076
|s e284de5e-ad90-5b19-abd4-19b0960e9cf1
|
928 |
|
|
|t Library of Congress classification
|a QC174.12.S52 1994
|l JCL
|c JCL-Sci
|i 6088611
|
928 |
|
|
|t Library of Congress classification
|a QC174.12.S52 1994
|l JCL
|c JCL-Sci
|i 6088612
|
927 |
|
|
|t Library of Congress classification
|a QC174.12.S52 1994
|l JCL
|c JCL-SciRes
|e CRERAR
|b 45383846
|i 5009171
|
927 |
|
|
|t Library of Congress classification
|a QC174.12.S52 1994
|l JCL
|c JCL-SciRes
|e CRERAR
|b 63344127
|i 5009172
|