Details
Quantum Mechanics via Lie Algebras
ISSN 1. Aufl.
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189,95 € |
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| Verlag: | De Gruyter |
| Format: | EPUB |
| Veröffentl.: | 07.10.2024 |
| ISBN/EAN: | 9783110406245 |
| Sprache: | englisch |
| Anzahl Seiten: | 504 |
DRM-geschütztes eBook, Sie benötigen z.B. Adobe Digital Editions und eine Adobe ID zum Lesen.
Beschreibungen
This monograph introduces mathematicians, physicists, and engineers to the ideas relating quantum mechanics and symmetries - both described in terms of Lie algebras and Lie groups. The exposition of quantum mechanics from this point of view reveals that classical mechanics and quantum mechanics are very much alike. Written by a mathematician and a physicist, this book is (like a math book) about precise concepts and exact results in classical mechanics and quantum mechanics, but motivated and discussed (like a physics book) in terms of their physical meaning. The reader can focus on the simplicity and beauty of theoretical physics, without getting lost in a jungle of techniques for estimating or calculating quantities of interest.
<p>Preface</p>
<p>I An invitation to quantum mechanics<br>1 Motivation<br>1.1 Classical mechanics<br>1.2 Relativity theory<br>1.3 Statistical mechanics and thermodynamics<br>1.4 Hamiltonian mechanics<br>1.5 Quantum mechanics<br>1.6 Quantum field theory<br>1.7 The Schrödinger picture<br>1.8 The Heisenberg picture<br>1.9 Outline of the book<br>2 The simplest quantum system<br>2.1 Matrices, relativity and quantum theory<br>2.2 Continuous motions and matrix groups<br>2.3 Infinitesimal motions and matrix Lie algebras<br>2.4 Uniform motions and the matrix exponential<br>2.5 Volume preservation and special linear groups<br>2.6 The vector product, quaternions, and SL(2,C)<br>2.7 The Hamiltonian form of a Lie algebra <br>2.8 Atomic energy levels and unitary groups <br>2.9 Qubits and Bloch sphere <br>2.10 Polarized light and beam transformations <br>2.11 Spin and spin coherent states <br>2.12 Particles and detection probabilities <br>2.13 Photons on demand <br>2.14 Unitary representations of SU(2) <br>3 The symmetries of the universe <br>3.1 Rotations and SO(n) <br>3.2 3-dimensional rotations and SO(3) <br>3.3 Rotations and quaternions <br>3.4 Rotations and SU(2) <br>3.5 Angular velocity <br>3.6 Rigid motions and Euclidean groups <br>3.7 Connected subgroups of SL(2,R) <br>3.8 Connected subgroups of SL(3,R) <br>3.9 Classical mechanics and Heisenberg groups <br>3.10 Angular momentum, isospin, quarks <br>3.11 Connected subgroups of SL(4,R) <br>3.12 The Galilean group <br>3.13 The Lorentz groups O(1, 3), SO(1, 3), SO(1, 3)0 <br>3.14 The Poincare group ISO(1, 3) <br>3.15 A Lorentz invariant measure <br>3.16 Kepler's laws, the hydrogen atom, and SO(4) <br>3.17 The periodic systemand the conformal group SO(2, 4) <br>3.18 The interacting boson model and U(6) <br>3.19 Casimirs <br>3.20 Unitary representations of the Poincaré group <br>3.21 Some representations of the Poincaré group <br>3.22 Elementary particles <br>3.23 The position operator <br>4 From the theoretical physics FAQ <br>4.1 To be done <br>4.2 Postulates for the formal core of quantum mechanics <br>4.3 Lie groups and Lie algebras <br>4.4 The Galilei group as contraction of the Poincare group <br>4.5 Representations of the Poincare group <br>4.6 Forms of relativistic dynamics <br>4.7 Is there a multiparticle relativistic quantum mechanics? <br>4.8 What is a photon? <br>4.9 Particle positions and the position operator <br>4.10 Localization and position operators <br>4.11 SO(3) = SU(2)/Z2 <br>5 Classical oscillating systems <br>5.1 Systems of damped oscillators <br>5.2 The classical anharmonic oscillator <br>5.3 Harmonic oscillators and linear field equations <br>5.4 Alpha rays <br>5.5 Beta rays <br>5.6 Light rays and gamma rays <br>6 Spectral analysis <br>6.1 The quantum spectrum <br>6.2 Probing the spectrum of a system <br>6.3 The early history of quantum mechanics <br>6.4 The spectrum of many-particle systems <br>6.5 Black body radiation<br>6.6 Derivation of Planckés law<br>6.7 Stefan´s law and Wien´s displacement law</p>
<p>II Statistical mechanics<br>7 Phenomenological thermodynamics <br>7.1 Standard thermodynamical systems <br>7.2 The laws of thermodynamics <br>7.3 Consequences of the first law <br>7.4 Consequences of the second law <br>7.5 The approach to equilibrium <br>7.6 Description levels <br>8 Quantities, states, and statistics <br>8.1 Quantities <br>8.2 Gibbs states <br>8.3 Kubo product and generating functional <br>8.4 Limit resolution and uncertainty <br>9 The laws of thermodynamics <br>9.1 The zeroth law: Thermal states <br>9.2 The equation of state <br>9.3 The first law: Energy balance <br>9.4 The second law: Extremal principles <br>9.5 The third law: Quantization <br>10 Models, statistics, and measurements <br>10.1 Description levels <br>10.2 Local, microlocal, and quantum equilibrium <br>10.3 Statistics and probability <br>10.4 Classical measurements <br>10.5 Quantum probability <br>10.6 Entropy and information theory <br>10.7 Subjective probability</p>
<p>III Lie algebras and Poisson algebras<br>11 Lie algebras<br>11.1 Basic definitions <br>11.2 Lie algebras from derivations <br>11.3 Linear groups and their Lie algebras <br>11.4 Classical Lie groups and their Lie algebras <br>11.5 Heisenberg algebras and Heisenberg groups <br>11.6 Lie-algebras <br>12 Mechanics in Poisson algebras <br>12.1 Poisson algebras <br>12.2 Rotating rigid bodies <br>12.3 Rotations and angular momentum <br>12.4 Classical rigid body dynamics <br>12.5 Lie-Poisson algebras <br>12.6 Classical symplectic mechanics <br>12.7 Molecular mechanics <br>12.8 An outlook to quantum field theory <br>13 Representation and classification <br>13.1 Poisson representations <br>13.2 Linear representations <br>13.3 Finite-dimensional representations <br>13.4 Representations of Lie groups <br>13.5 Finite-dimensional semisimple Lie algebras <br>13.6 Automorphisms and coadjoint orbits </p>
<p>IV Nonequilibrium thermodynamics <br>14 Markov Processes <br>14.1 Activities <br>14.2 Processes <br>14.3 Forward morphisms and quantum dynamical semigroups <br>14.4 Forward derivations <br>14.5 Single-time, autonomous Markov processes <br>15 Diffusion processes <br>15.1 Stochastic differential equations <br>15.2 Closed diffusion processes <br>15.3 Ornstein-Uhlenbeck processes <br>15.4 Linear processes with memory <br>15.5 Dissipative Hamiltonian Systems <br>16 Collective Processes <br>16.1 The master equation <br>16.2 Canonical form and thermodynamic limit <br>16.3 Stirred chemical reactions <br>16.4 Linear response theory <br>16.5 Open system <br>16.6 Some philosophical afterthoughts <br>V Mechanics and differential geometry <br>17 Fields, forms, and derivatives <br>17.1 Scalar fields and vector fields <br>17.2 Multilinear forms <br>17.3 Exterior calculus <br>17.4 Manifolds as differential geometries <br>17.5 Manifolds as topological spaces <br>17.6 Noncommutative geometry <br>17.7 Lie groups as manifolds <br>18 Conservative mechanics on manifolds <br>18.1 Poisson algebras from closed 2-forms <br>18.2 Conservative Hamiltonian dynamics <br>18.3 Constrained Hamiltonian dynamics <br>18.4 Lagrangian mechanics <br>19 Hamiltonian quantum mechanics<br>19.1 Quantum dynamics as symplectic motion <br>19.2 Quantum-classical dynamics <br>19.3 Deformation quantization<br>19.4 The Wigner transform</p>
<p>VI Representations and spectroscopy<br>20 Harmonic oscillators and coherent states<br>20.1 The classical harmonic oscillator<br>20.2 Quantizing the harmonic oscillator<br>20.3 Representations of the Heisenberg algebra <br>20.4 Bras and Kets<br>20.5 Boson Fock space<br>20.6 Bargmann.Fock representation<br>20.7 Coherent states for the harmonic oscillator <br>20.8 Monochromatic beams and coherent states <br>21 Spin and fermions <br>21.1 Fermion Fock space <br>21.2 Extension to many degrees of freedom <br>21.3 Exterior algebra representation <br>21.4 Spin and metaplectic representation <br>22 Highest weight representations <br>22.1 Triangular decompositions <br>22.2 Triangulated Lie algebras of rank and degree one <br>22.3 Unitary representations of SU(2) and SO(3) <br>22.4 Some unitary highest weight representations <br>23 Spectroscopy and spectra <br>23.1 Introduction and historical background <br>23.2 Spectra of systems of particles <br>23.3 Examples of spectra<br>23.4 Dynamical symmetries<br>23.5 The hydrogen atom<br>23.6 Chains of subalgebras</p>
<p>References</p>
<p>I An invitation to quantum mechanics<br>1 Motivation<br>1.1 Classical mechanics<br>1.2 Relativity theory<br>1.3 Statistical mechanics and thermodynamics<br>1.4 Hamiltonian mechanics<br>1.5 Quantum mechanics<br>1.6 Quantum field theory<br>1.7 The Schrödinger picture<br>1.8 The Heisenberg picture<br>1.9 Outline of the book<br>2 The simplest quantum system<br>2.1 Matrices, relativity and quantum theory<br>2.2 Continuous motions and matrix groups<br>2.3 Infinitesimal motions and matrix Lie algebras<br>2.4 Uniform motions and the matrix exponential<br>2.5 Volume preservation and special linear groups<br>2.6 The vector product, quaternions, and SL(2,C)<br>2.7 The Hamiltonian form of a Lie algebra <br>2.8 Atomic energy levels and unitary groups <br>2.9 Qubits and Bloch sphere <br>2.10 Polarized light and beam transformations <br>2.11 Spin and spin coherent states <br>2.12 Particles and detection probabilities <br>2.13 Photons on demand <br>2.14 Unitary representations of SU(2) <br>3 The symmetries of the universe <br>3.1 Rotations and SO(n) <br>3.2 3-dimensional rotations and SO(3) <br>3.3 Rotations and quaternions <br>3.4 Rotations and SU(2) <br>3.5 Angular velocity <br>3.6 Rigid motions and Euclidean groups <br>3.7 Connected subgroups of SL(2,R) <br>3.8 Connected subgroups of SL(3,R) <br>3.9 Classical mechanics and Heisenberg groups <br>3.10 Angular momentum, isospin, quarks <br>3.11 Connected subgroups of SL(4,R) <br>3.12 The Galilean group <br>3.13 The Lorentz groups O(1, 3), SO(1, 3), SO(1, 3)0 <br>3.14 The Poincare group ISO(1, 3) <br>3.15 A Lorentz invariant measure <br>3.16 Kepler's laws, the hydrogen atom, and SO(4) <br>3.17 The periodic systemand the conformal group SO(2, 4) <br>3.18 The interacting boson model and U(6) <br>3.19 Casimirs <br>3.20 Unitary representations of the Poincaré group <br>3.21 Some representations of the Poincaré group <br>3.22 Elementary particles <br>3.23 The position operator <br>4 From the theoretical physics FAQ <br>4.1 To be done <br>4.2 Postulates for the formal core of quantum mechanics <br>4.3 Lie groups and Lie algebras <br>4.4 The Galilei group as contraction of the Poincare group <br>4.5 Representations of the Poincare group <br>4.6 Forms of relativistic dynamics <br>4.7 Is there a multiparticle relativistic quantum mechanics? <br>4.8 What is a photon? <br>4.9 Particle positions and the position operator <br>4.10 Localization and position operators <br>4.11 SO(3) = SU(2)/Z2 <br>5 Classical oscillating systems <br>5.1 Systems of damped oscillators <br>5.2 The classical anharmonic oscillator <br>5.3 Harmonic oscillators and linear field equations <br>5.4 Alpha rays <br>5.5 Beta rays <br>5.6 Light rays and gamma rays <br>6 Spectral analysis <br>6.1 The quantum spectrum <br>6.2 Probing the spectrum of a system <br>6.3 The early history of quantum mechanics <br>6.4 The spectrum of many-particle systems <br>6.5 Black body radiation<br>6.6 Derivation of Planckés law<br>6.7 Stefan´s law and Wien´s displacement law</p>
<p>II Statistical mechanics<br>7 Phenomenological thermodynamics <br>7.1 Standard thermodynamical systems <br>7.2 The laws of thermodynamics <br>7.3 Consequences of the first law <br>7.4 Consequences of the second law <br>7.5 The approach to equilibrium <br>7.6 Description levels <br>8 Quantities, states, and statistics <br>8.1 Quantities <br>8.2 Gibbs states <br>8.3 Kubo product and generating functional <br>8.4 Limit resolution and uncertainty <br>9 The laws of thermodynamics <br>9.1 The zeroth law: Thermal states <br>9.2 The equation of state <br>9.3 The first law: Energy balance <br>9.4 The second law: Extremal principles <br>9.5 The third law: Quantization <br>10 Models, statistics, and measurements <br>10.1 Description levels <br>10.2 Local, microlocal, and quantum equilibrium <br>10.3 Statistics and probability <br>10.4 Classical measurements <br>10.5 Quantum probability <br>10.6 Entropy and information theory <br>10.7 Subjective probability</p>
<p>III Lie algebras and Poisson algebras<br>11 Lie algebras<br>11.1 Basic definitions <br>11.2 Lie algebras from derivations <br>11.3 Linear groups and their Lie algebras <br>11.4 Classical Lie groups and their Lie algebras <br>11.5 Heisenberg algebras and Heisenberg groups <br>11.6 Lie-algebras <br>12 Mechanics in Poisson algebras <br>12.1 Poisson algebras <br>12.2 Rotating rigid bodies <br>12.3 Rotations and angular momentum <br>12.4 Classical rigid body dynamics <br>12.5 Lie-Poisson algebras <br>12.6 Classical symplectic mechanics <br>12.7 Molecular mechanics <br>12.8 An outlook to quantum field theory <br>13 Representation and classification <br>13.1 Poisson representations <br>13.2 Linear representations <br>13.3 Finite-dimensional representations <br>13.4 Representations of Lie groups <br>13.5 Finite-dimensional semisimple Lie algebras <br>13.6 Automorphisms and coadjoint orbits </p>
<p>IV Nonequilibrium thermodynamics <br>14 Markov Processes <br>14.1 Activities <br>14.2 Processes <br>14.3 Forward morphisms and quantum dynamical semigroups <br>14.4 Forward derivations <br>14.5 Single-time, autonomous Markov processes <br>15 Diffusion processes <br>15.1 Stochastic differential equations <br>15.2 Closed diffusion processes <br>15.3 Ornstein-Uhlenbeck processes <br>15.4 Linear processes with memory <br>15.5 Dissipative Hamiltonian Systems <br>16 Collective Processes <br>16.1 The master equation <br>16.2 Canonical form and thermodynamic limit <br>16.3 Stirred chemical reactions <br>16.4 Linear response theory <br>16.5 Open system <br>16.6 Some philosophical afterthoughts <br>V Mechanics and differential geometry <br>17 Fields, forms, and derivatives <br>17.1 Scalar fields and vector fields <br>17.2 Multilinear forms <br>17.3 Exterior calculus <br>17.4 Manifolds as differential geometries <br>17.5 Manifolds as topological spaces <br>17.6 Noncommutative geometry <br>17.7 Lie groups as manifolds <br>18 Conservative mechanics on manifolds <br>18.1 Poisson algebras from closed 2-forms <br>18.2 Conservative Hamiltonian dynamics <br>18.3 Constrained Hamiltonian dynamics <br>18.4 Lagrangian mechanics <br>19 Hamiltonian quantum mechanics<br>19.1 Quantum dynamics as symplectic motion <br>19.2 Quantum-classical dynamics <br>19.3 Deformation quantization<br>19.4 The Wigner transform</p>
<p>VI Representations and spectroscopy<br>20 Harmonic oscillators and coherent states<br>20.1 The classical harmonic oscillator<br>20.2 Quantizing the harmonic oscillator<br>20.3 Representations of the Heisenberg algebra <br>20.4 Bras and Kets<br>20.5 Boson Fock space<br>20.6 Bargmann.Fock representation<br>20.7 Coherent states for the harmonic oscillator <br>20.8 Monochromatic beams and coherent states <br>21 Spin and fermions <br>21.1 Fermion Fock space <br>21.2 Extension to many degrees of freedom <br>21.3 Exterior algebra representation <br>21.4 Spin and metaplectic representation <br>22 Highest weight representations <br>22.1 Triangular decompositions <br>22.2 Triangulated Lie algebras of rank and degree one <br>22.3 Unitary representations of SU(2) and SO(3) <br>22.4 Some unitary highest weight representations <br>23 Spectroscopy and spectra <br>23.1 Introduction and historical background <br>23.2 Spectra of systems of particles <br>23.3 Examples of spectra<br>23.4 Dynamical symmetries<br>23.5 The hydrogen atom<br>23.6 Chains of subalgebras</p>
<p>References</p>
<p><strong>Arnold Neumaier</strong> and <strong>Dennis Westra</strong>, University of Vienna, Austria.</p>
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