- Gebundenes Buch
- Merkliste
- Auf die Merkliste
- Bewerten Bewerten
- Teilen
- Produkt teilen
- Produkterinnerung
- Produkterinnerung
This book serves as introduction to quantum theory with emphasis on dynamical behaviour and applications of quantum mechanics, with minimal discussion of formalism. The goal is to help engineering and physics students begin to learn the tools for a quantum toolbox they will need to work in this area.
Andere Kunden interessierten sich auch für
- Walter KoechnerSolid-State Lasers41,99 €
- D.F. WallsQuantum Optics69,54 €
- Brian K RidleyQuantum Processes in Semiconductors199,99 €
- Debasish DattaOptical Networks123,99 €
- Harvey N HolzmanModern Commercial Wiring156,99 €
- Floyd M MixHouse Wiring Simplified73,99 €
- Joseph MoravekElectricity for Hvacr251,99 €
-
-
-
This book serves as introduction to quantum theory with emphasis on dynamical behaviour and applications of quantum mechanics, with minimal discussion of formalism. The goal is to help engineering and physics students begin to learn the tools for a quantum toolbox they will need to work in this area.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Hurst & Co.
- Seitenzahl: 400
- Erscheinungstermin: 30. Juni 2021
- Englisch
- Abmessung: 249mm x 196mm x 25mm
- Gewicht: 1002g
- ISBN-13: 9780192895073
- ISBN-10: 0192895079
- Artikelnr.: 60780752
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
- Verlag: Hurst & Co.
- Seitenzahl: 400
- Erscheinungstermin: 30. Juni 2021
- Englisch
- Abmessung: 249mm x 196mm x 25mm
- Gewicht: 1002g
- ISBN-13: 9780192895073
- ISBN-10: 0192895079
- Artikelnr.: 60780752
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
Duncan G. Steel, The Robert J. Hiller Professor, Professor of Electrical Engineering and Computer Science, Professor of Physics, The University of Michigan - Ann Arbor. PhD in 1976 in Electrical and Nuclear Science, University of Michigan. Guggenheim Fellow (1999), APS Isakson Prize (2010), Elected Fellow of APS, OSA, and IEEE. 10 years at Hughes Research Laboratories (senior staff physicist), faculty at the University of Michigan (1985-), Area Chair for Optics and Director of the Optical Sciences Laboratory 1988-2007, Director of Biophysics 2007-2009.
* Chapter 1. Introduction to Applied Quantum Mechanics - Why quantum
behavior is impacting technology.
* Chapter 2. Nano Mechanical Oscillator and Basic Dynamics: Part I
* 2.1: Introduction
* 2.2: The Classical Approach: Finding
* 2.3: The Quantum Approach: Finding
* 2.4: Is it Classical or Quantum?
* 2.5: What is Knowable in a Quantum System?
* 2.6: Coherent Superposition States and Coherent Dynamics
* 2.7: The Particle and the Wave
* 2.8: Summary
* Chapter 3. Free Particle, Wave Packet and Dynamics, Quantum Dots and
Defects/Traps Scattering and Transport.
* 3.1: Introduction
* 3.2: The Free Particle
* 3.3: Localized State in Free Space: The Wave Packet
* 3.4: Nano-Heterostructures: Quantum Dots and Deep Traps
* 3.5: A Particle Trapped in a Shallow Defect
* 3.6: A Particle Trapped in a Point Defect Represented by a Dirac
Delta-Function Potential
* 3.7: Physical Interpretation of the Dirac -function potential
* 3.8: Summary
* Chapter 4. Periodic Hamiltonians and the Emergence of Band Structure:
The Bloch Theorem and the Dirac Kronig-Penney model.
* 4.1: Introduction
* 4.2: The Translation Operator
* 4.3: Crystals and Periodic Potentials: The Bloch Theorem and the
Dirac Kronig-Penney Model
* 4.4: Summary
* Chapter 5. Scattering, Quantum Current, and Resonant Tunneling
* 5.1: Introduction
* 5.2: Scattering
* 5.3: Tunneling Through a Repulsive Point Defect Represented by a
Dirac -Function Potential
* 5.4: Resonant Tunneling
* 5.5: Summary
* Chapter 6. Bound States in 3-dimensions: The Atom.
* 6.1: Introduction
* 6.2: The Hydrogenic Atom
* 6.3: Summary
* Chapter 7. The New Design Rules for Quantum: The Postulates.
* 7.1: Introduction
* 7.2: The Postulates of Quantum Mechanics
* 7.3: The Heisenberg Uncertainty Principle: The Minimum Uncertainty
State
* 7.4: Interpreting the Expansion Coefficients: Relating Functional
Form to Dirac Form
* 7.5: Summary
* Chapter 8. Heisenberg Matrix Approach: Nano-Mechanical Oscillator and
the Quantum LC Circuit.
* 8.1: Introduction
* 8.2: Heisenberg or Matrix Approach to Solving the Time Independent
Schrödinger Equation
* 8.3: Matrix Representation of Operators and Eigenvectors in Quantum
Mechanics
* 8.4: The Quantum LC Circuit
* 8.5: Summary
* Chapter 9. Quantum Dynamics: Rabi Oscillations and Quantum
Flip-Flops.
* 9.1: Introduction
* 9.2: Time Evolution Operator
* 9.3: The Heisenberg Picture of Dynamics
* 9.4: The Interaction Picture
* 9.5: A Quantum Flip-Flop: Coherent Control of a Two-Level System and
Rabi Oscillations
* 9.6: Summary
* Chapter 10. The Quantum Gyroscope: The Emergence of Spin.
* 10.1: Introduction
* 10.2: Angular Momentum with the Heisenberg Approach
* 10.3: Intrinsic Angular Momentum: Spin
* 10.4: The Bloch Sphere and Spin
* 10.5: Addition of Angular Momentum
* 10.6: Angular Momentum and the Rotation Operator
* 10.7: Summary
* Chapter 11. Time Independent and Time Dependent Perturbation Theory.
* 11.1: Introduction
* 11.2: Time Independent Perturbation Theory.
* 11.3: Time Dependent Perturbation Theory: Fermi's Golden Rule
* 11.4: Summary
* Chapter 12. Bosons and Fermions: Indistinguishable particles with
intrinsic spin.
* 12.1: Introduction
* 12.2: Eigenfunctions and Eigenvalues of the Exchange Operator
* 12.3: The Exchange Symmetry Postulate: Bosons and Fermions
* 12.4: The Heitler-London Model
* 12.5: Summary
* Chapter 13. Quantum Measurement and Entanglement: Wave-Function
Collapse
* 13.1: Introduction
* 13.2: Quantum Measurement
* 13.3: Quantum Entanglement and the Impact of Measurement
* 13.4: Quantum Teleportation
* 13.5: Summary
* Chapter 14. Loss and Decoherence: The RLC Circuit
* 14.1: Introduction
* 14.2: Coupling to a Continuum of States: The Weisskopf-Wigner
Approximation
* 14.3: Decay in the Nano-Vibrator Problem
* 14.4: The RLC Circuit
* 14.5: Summary
* Chapter 15. The Quantum Radiation Field: Spontaneous Emission and
Entangled Photons
* 15.1: Introduction
* 15.2: Finding the Hamiltonian for the Transverse Electromagnetic
Field
* 15.3: Quantizing the Field
* 15.4: Spontaneous Emission
* 15.5: The Effects of the Quantum Vacuum on Linear Absorption and
Dispersion
* 15.6: Rabi Oscillations in the Vacuum: The Jaynes Cummings
Hamiltonian
* 15.7: Summary
* Chapter 16. Atomic Operators
* 16.1: Introduction
* 16.2: Defining the Atomic Operators
* 16.3: The Physical Meaning of the Atomic Operators
* 16.4: The Atomic Operators in the Heisenberg Picture
* 16.5: The Exact Solution for the Atomic Operators for a Monochromatic
Field
* 16.6: The Operator Equations of Motion Including Spontaneous Emission
* Chapter 17. Quantum Electromagneticst
* 17.1: Introduction
* 17.2: The Number State Representation
* 17.3: The Coherent State
* 17.4: Quantum Beam Splitter: Quantum Interference
* 17.5: Resonant Rayleigh Scattering: A Single Quantum Emitter
* 17.6: Creating a Quantum Entangled State Between a Photon and an
Electron
* 17.7: Engineering the Quantum Vacuum
* 17.8: Summary
* Chapter 18. The Density Matrix: Bloch Equations
* 18.1: Introduction
* 18.2: The Density Matrix Operator
* 18.3: The Density Matrix Equations Including Relaxation
* 18.4: Solving the Reduced Density Matrix for a Two-Level System in
the Presence of Resonant Classical Electromagnetic Field
* 18.5: Rate Equation Approximation
* 18.6: The Three-Level System: Emerging Importance in Quantum
Technology
* 18.7: Summary
* Appendices
* A: Essential Mathematics Review
* B: Power Series for important Functions
* C: Properties and Representations for the Dirac Delta Function
* D: Vector Calculus and Vector IdentifiesThe Electromagnetic
Hamiltonian and the Göpert-Mayer Transformation
* E: The Electromagnetic Hamiltonian and the Göpert-Mayer
Transformation
* F: Maxwell's Equations in Media, the Wave Equation and Coupling to a
two-level system
* G: Wigner-Eckart Theorem for evaluating matrix elements.
behavior is impacting technology.
* Chapter 2. Nano Mechanical Oscillator and Basic Dynamics: Part I
* 2.1: Introduction
* 2.2: The Classical Approach: Finding
* 2.3: The Quantum Approach: Finding
* 2.4: Is it Classical or Quantum?
* 2.5: What is Knowable in a Quantum System?
* 2.6: Coherent Superposition States and Coherent Dynamics
* 2.7: The Particle and the Wave
* 2.8: Summary
* Chapter 3. Free Particle, Wave Packet and Dynamics, Quantum Dots and
Defects/Traps Scattering and Transport.
* 3.1: Introduction
* 3.2: The Free Particle
* 3.3: Localized State in Free Space: The Wave Packet
* 3.4: Nano-Heterostructures: Quantum Dots and Deep Traps
* 3.5: A Particle Trapped in a Shallow Defect
* 3.6: A Particle Trapped in a Point Defect Represented by a Dirac
Delta-Function Potential
* 3.7: Physical Interpretation of the Dirac -function potential
* 3.8: Summary
* Chapter 4. Periodic Hamiltonians and the Emergence of Band Structure:
The Bloch Theorem and the Dirac Kronig-Penney model.
* 4.1: Introduction
* 4.2: The Translation Operator
* 4.3: Crystals and Periodic Potentials: The Bloch Theorem and the
Dirac Kronig-Penney Model
* 4.4: Summary
* Chapter 5. Scattering, Quantum Current, and Resonant Tunneling
* 5.1: Introduction
* 5.2: Scattering
* 5.3: Tunneling Through a Repulsive Point Defect Represented by a
Dirac -Function Potential
* 5.4: Resonant Tunneling
* 5.5: Summary
* Chapter 6. Bound States in 3-dimensions: The Atom.
* 6.1: Introduction
* 6.2: The Hydrogenic Atom
* 6.3: Summary
* Chapter 7. The New Design Rules for Quantum: The Postulates.
* 7.1: Introduction
* 7.2: The Postulates of Quantum Mechanics
* 7.3: The Heisenberg Uncertainty Principle: The Minimum Uncertainty
State
* 7.4: Interpreting the Expansion Coefficients: Relating Functional
Form to Dirac Form
* 7.5: Summary
* Chapter 8. Heisenberg Matrix Approach: Nano-Mechanical Oscillator and
the Quantum LC Circuit.
* 8.1: Introduction
* 8.2: Heisenberg or Matrix Approach to Solving the Time Independent
Schrödinger Equation
* 8.3: Matrix Representation of Operators and Eigenvectors in Quantum
Mechanics
* 8.4: The Quantum LC Circuit
* 8.5: Summary
* Chapter 9. Quantum Dynamics: Rabi Oscillations and Quantum
Flip-Flops.
* 9.1: Introduction
* 9.2: Time Evolution Operator
* 9.3: The Heisenberg Picture of Dynamics
* 9.4: The Interaction Picture
* 9.5: A Quantum Flip-Flop: Coherent Control of a Two-Level System and
Rabi Oscillations
* 9.6: Summary
* Chapter 10. The Quantum Gyroscope: The Emergence of Spin.
* 10.1: Introduction
* 10.2: Angular Momentum with the Heisenberg Approach
* 10.3: Intrinsic Angular Momentum: Spin
* 10.4: The Bloch Sphere and Spin
* 10.5: Addition of Angular Momentum
* 10.6: Angular Momentum and the Rotation Operator
* 10.7: Summary
* Chapter 11. Time Independent and Time Dependent Perturbation Theory.
* 11.1: Introduction
* 11.2: Time Independent Perturbation Theory.
* 11.3: Time Dependent Perturbation Theory: Fermi's Golden Rule
* 11.4: Summary
* Chapter 12. Bosons and Fermions: Indistinguishable particles with
intrinsic spin.
* 12.1: Introduction
* 12.2: Eigenfunctions and Eigenvalues of the Exchange Operator
* 12.3: The Exchange Symmetry Postulate: Bosons and Fermions
* 12.4: The Heitler-London Model
* 12.5: Summary
* Chapter 13. Quantum Measurement and Entanglement: Wave-Function
Collapse
* 13.1: Introduction
* 13.2: Quantum Measurement
* 13.3: Quantum Entanglement and the Impact of Measurement
* 13.4: Quantum Teleportation
* 13.5: Summary
* Chapter 14. Loss and Decoherence: The RLC Circuit
* 14.1: Introduction
* 14.2: Coupling to a Continuum of States: The Weisskopf-Wigner
Approximation
* 14.3: Decay in the Nano-Vibrator Problem
* 14.4: The RLC Circuit
* 14.5: Summary
* Chapter 15. The Quantum Radiation Field: Spontaneous Emission and
Entangled Photons
* 15.1: Introduction
* 15.2: Finding the Hamiltonian for the Transverse Electromagnetic
Field
* 15.3: Quantizing the Field
* 15.4: Spontaneous Emission
* 15.5: The Effects of the Quantum Vacuum on Linear Absorption and
Dispersion
* 15.6: Rabi Oscillations in the Vacuum: The Jaynes Cummings
Hamiltonian
* 15.7: Summary
* Chapter 16. Atomic Operators
* 16.1: Introduction
* 16.2: Defining the Atomic Operators
* 16.3: The Physical Meaning of the Atomic Operators
* 16.4: The Atomic Operators in the Heisenberg Picture
* 16.5: The Exact Solution for the Atomic Operators for a Monochromatic
Field
* 16.6: The Operator Equations of Motion Including Spontaneous Emission
* Chapter 17. Quantum Electromagneticst
* 17.1: Introduction
* 17.2: The Number State Representation
* 17.3: The Coherent State
* 17.4: Quantum Beam Splitter: Quantum Interference
* 17.5: Resonant Rayleigh Scattering: A Single Quantum Emitter
* 17.6: Creating a Quantum Entangled State Between a Photon and an
Electron
* 17.7: Engineering the Quantum Vacuum
* 17.8: Summary
* Chapter 18. The Density Matrix: Bloch Equations
* 18.1: Introduction
* 18.2: The Density Matrix Operator
* 18.3: The Density Matrix Equations Including Relaxation
* 18.4: Solving the Reduced Density Matrix for a Two-Level System in
the Presence of Resonant Classical Electromagnetic Field
* 18.5: Rate Equation Approximation
* 18.6: The Three-Level System: Emerging Importance in Quantum
Technology
* 18.7: Summary
* Appendices
* A: Essential Mathematics Review
* B: Power Series for important Functions
* C: Properties and Representations for the Dirac Delta Function
* D: Vector Calculus and Vector IdentifiesThe Electromagnetic
Hamiltonian and the Göpert-Mayer Transformation
* E: The Electromagnetic Hamiltonian and the Göpert-Mayer
Transformation
* F: Maxwell's Equations in Media, the Wave Equation and Coupling to a
two-level system
* G: Wigner-Eckart Theorem for evaluating matrix elements.
* Chapter 1. Introduction to Applied Quantum Mechanics - Why quantum
behavior is impacting technology.
* Chapter 2. Nano Mechanical Oscillator and Basic Dynamics: Part I
* 2.1: Introduction
* 2.2: The Classical Approach: Finding
* 2.3: The Quantum Approach: Finding
* 2.4: Is it Classical or Quantum?
* 2.5: What is Knowable in a Quantum System?
* 2.6: Coherent Superposition States and Coherent Dynamics
* 2.7: The Particle and the Wave
* 2.8: Summary
* Chapter 3. Free Particle, Wave Packet and Dynamics, Quantum Dots and
Defects/Traps Scattering and Transport.
* 3.1: Introduction
* 3.2: The Free Particle
* 3.3: Localized State in Free Space: The Wave Packet
* 3.4: Nano-Heterostructures: Quantum Dots and Deep Traps
* 3.5: A Particle Trapped in a Shallow Defect
* 3.6: A Particle Trapped in a Point Defect Represented by a Dirac
Delta-Function Potential
* 3.7: Physical Interpretation of the Dirac -function potential
* 3.8: Summary
* Chapter 4. Periodic Hamiltonians and the Emergence of Band Structure:
The Bloch Theorem and the Dirac Kronig-Penney model.
* 4.1: Introduction
* 4.2: The Translation Operator
* 4.3: Crystals and Periodic Potentials: The Bloch Theorem and the
Dirac Kronig-Penney Model
* 4.4: Summary
* Chapter 5. Scattering, Quantum Current, and Resonant Tunneling
* 5.1: Introduction
* 5.2: Scattering
* 5.3: Tunneling Through a Repulsive Point Defect Represented by a
Dirac -Function Potential
* 5.4: Resonant Tunneling
* 5.5: Summary
* Chapter 6. Bound States in 3-dimensions: The Atom.
* 6.1: Introduction
* 6.2: The Hydrogenic Atom
* 6.3: Summary
* Chapter 7. The New Design Rules for Quantum: The Postulates.
* 7.1: Introduction
* 7.2: The Postulates of Quantum Mechanics
* 7.3: The Heisenberg Uncertainty Principle: The Minimum Uncertainty
State
* 7.4: Interpreting the Expansion Coefficients: Relating Functional
Form to Dirac Form
* 7.5: Summary
* Chapter 8. Heisenberg Matrix Approach: Nano-Mechanical Oscillator and
the Quantum LC Circuit.
* 8.1: Introduction
* 8.2: Heisenberg or Matrix Approach to Solving the Time Independent
Schrödinger Equation
* 8.3: Matrix Representation of Operators and Eigenvectors in Quantum
Mechanics
* 8.4: The Quantum LC Circuit
* 8.5: Summary
* Chapter 9. Quantum Dynamics: Rabi Oscillations and Quantum
Flip-Flops.
* 9.1: Introduction
* 9.2: Time Evolution Operator
* 9.3: The Heisenberg Picture of Dynamics
* 9.4: The Interaction Picture
* 9.5: A Quantum Flip-Flop: Coherent Control of a Two-Level System and
Rabi Oscillations
* 9.6: Summary
* Chapter 10. The Quantum Gyroscope: The Emergence of Spin.
* 10.1: Introduction
* 10.2: Angular Momentum with the Heisenberg Approach
* 10.3: Intrinsic Angular Momentum: Spin
* 10.4: The Bloch Sphere and Spin
* 10.5: Addition of Angular Momentum
* 10.6: Angular Momentum and the Rotation Operator
* 10.7: Summary
* Chapter 11. Time Independent and Time Dependent Perturbation Theory.
* 11.1: Introduction
* 11.2: Time Independent Perturbation Theory.
* 11.3: Time Dependent Perturbation Theory: Fermi's Golden Rule
* 11.4: Summary
* Chapter 12. Bosons and Fermions: Indistinguishable particles with
intrinsic spin.
* 12.1: Introduction
* 12.2: Eigenfunctions and Eigenvalues of the Exchange Operator
* 12.3: The Exchange Symmetry Postulate: Bosons and Fermions
* 12.4: The Heitler-London Model
* 12.5: Summary
* Chapter 13. Quantum Measurement and Entanglement: Wave-Function
Collapse
* 13.1: Introduction
* 13.2: Quantum Measurement
* 13.3: Quantum Entanglement and the Impact of Measurement
* 13.4: Quantum Teleportation
* 13.5: Summary
* Chapter 14. Loss and Decoherence: The RLC Circuit
* 14.1: Introduction
* 14.2: Coupling to a Continuum of States: The Weisskopf-Wigner
Approximation
* 14.3: Decay in the Nano-Vibrator Problem
* 14.4: The RLC Circuit
* 14.5: Summary
* Chapter 15. The Quantum Radiation Field: Spontaneous Emission and
Entangled Photons
* 15.1: Introduction
* 15.2: Finding the Hamiltonian for the Transverse Electromagnetic
Field
* 15.3: Quantizing the Field
* 15.4: Spontaneous Emission
* 15.5: The Effects of the Quantum Vacuum on Linear Absorption and
Dispersion
* 15.6: Rabi Oscillations in the Vacuum: The Jaynes Cummings
Hamiltonian
* 15.7: Summary
* Chapter 16. Atomic Operators
* 16.1: Introduction
* 16.2: Defining the Atomic Operators
* 16.3: The Physical Meaning of the Atomic Operators
* 16.4: The Atomic Operators in the Heisenberg Picture
* 16.5: The Exact Solution for the Atomic Operators for a Monochromatic
Field
* 16.6: The Operator Equations of Motion Including Spontaneous Emission
* Chapter 17. Quantum Electromagneticst
* 17.1: Introduction
* 17.2: The Number State Representation
* 17.3: The Coherent State
* 17.4: Quantum Beam Splitter: Quantum Interference
* 17.5: Resonant Rayleigh Scattering: A Single Quantum Emitter
* 17.6: Creating a Quantum Entangled State Between a Photon and an
Electron
* 17.7: Engineering the Quantum Vacuum
* 17.8: Summary
* Chapter 18. The Density Matrix: Bloch Equations
* 18.1: Introduction
* 18.2: The Density Matrix Operator
* 18.3: The Density Matrix Equations Including Relaxation
* 18.4: Solving the Reduced Density Matrix for a Two-Level System in
the Presence of Resonant Classical Electromagnetic Field
* 18.5: Rate Equation Approximation
* 18.6: The Three-Level System: Emerging Importance in Quantum
Technology
* 18.7: Summary
* Appendices
* A: Essential Mathematics Review
* B: Power Series for important Functions
* C: Properties and Representations for the Dirac Delta Function
* D: Vector Calculus and Vector IdentifiesThe Electromagnetic
Hamiltonian and the Göpert-Mayer Transformation
* E: The Electromagnetic Hamiltonian and the Göpert-Mayer
Transformation
* F: Maxwell's Equations in Media, the Wave Equation and Coupling to a
two-level system
* G: Wigner-Eckart Theorem for evaluating matrix elements.
behavior is impacting technology.
* Chapter 2. Nano Mechanical Oscillator and Basic Dynamics: Part I
* 2.1: Introduction
* 2.2: The Classical Approach: Finding
* 2.3: The Quantum Approach: Finding
* 2.4: Is it Classical or Quantum?
* 2.5: What is Knowable in a Quantum System?
* 2.6: Coherent Superposition States and Coherent Dynamics
* 2.7: The Particle and the Wave
* 2.8: Summary
* Chapter 3. Free Particle, Wave Packet and Dynamics, Quantum Dots and
Defects/Traps Scattering and Transport.
* 3.1: Introduction
* 3.2: The Free Particle
* 3.3: Localized State in Free Space: The Wave Packet
* 3.4: Nano-Heterostructures: Quantum Dots and Deep Traps
* 3.5: A Particle Trapped in a Shallow Defect
* 3.6: A Particle Trapped in a Point Defect Represented by a Dirac
Delta-Function Potential
* 3.7: Physical Interpretation of the Dirac -function potential
* 3.8: Summary
* Chapter 4. Periodic Hamiltonians and the Emergence of Band Structure:
The Bloch Theorem and the Dirac Kronig-Penney model.
* 4.1: Introduction
* 4.2: The Translation Operator
* 4.3: Crystals and Periodic Potentials: The Bloch Theorem and the
Dirac Kronig-Penney Model
* 4.4: Summary
* Chapter 5. Scattering, Quantum Current, and Resonant Tunneling
* 5.1: Introduction
* 5.2: Scattering
* 5.3: Tunneling Through a Repulsive Point Defect Represented by a
Dirac -Function Potential
* 5.4: Resonant Tunneling
* 5.5: Summary
* Chapter 6. Bound States in 3-dimensions: The Atom.
* 6.1: Introduction
* 6.2: The Hydrogenic Atom
* 6.3: Summary
* Chapter 7. The New Design Rules for Quantum: The Postulates.
* 7.1: Introduction
* 7.2: The Postulates of Quantum Mechanics
* 7.3: The Heisenberg Uncertainty Principle: The Minimum Uncertainty
State
* 7.4: Interpreting the Expansion Coefficients: Relating Functional
Form to Dirac Form
* 7.5: Summary
* Chapter 8. Heisenberg Matrix Approach: Nano-Mechanical Oscillator and
the Quantum LC Circuit.
* 8.1: Introduction
* 8.2: Heisenberg or Matrix Approach to Solving the Time Independent
Schrödinger Equation
* 8.3: Matrix Representation of Operators and Eigenvectors in Quantum
Mechanics
* 8.4: The Quantum LC Circuit
* 8.5: Summary
* Chapter 9. Quantum Dynamics: Rabi Oscillations and Quantum
Flip-Flops.
* 9.1: Introduction
* 9.2: Time Evolution Operator
* 9.3: The Heisenberg Picture of Dynamics
* 9.4: The Interaction Picture
* 9.5: A Quantum Flip-Flop: Coherent Control of a Two-Level System and
Rabi Oscillations
* 9.6: Summary
* Chapter 10. The Quantum Gyroscope: The Emergence of Spin.
* 10.1: Introduction
* 10.2: Angular Momentum with the Heisenberg Approach
* 10.3: Intrinsic Angular Momentum: Spin
* 10.4: The Bloch Sphere and Spin
* 10.5: Addition of Angular Momentum
* 10.6: Angular Momentum and the Rotation Operator
* 10.7: Summary
* Chapter 11. Time Independent and Time Dependent Perturbation Theory.
* 11.1: Introduction
* 11.2: Time Independent Perturbation Theory.
* 11.3: Time Dependent Perturbation Theory: Fermi's Golden Rule
* 11.4: Summary
* Chapter 12. Bosons and Fermions: Indistinguishable particles with
intrinsic spin.
* 12.1: Introduction
* 12.2: Eigenfunctions and Eigenvalues of the Exchange Operator
* 12.3: The Exchange Symmetry Postulate: Bosons and Fermions
* 12.4: The Heitler-London Model
* 12.5: Summary
* Chapter 13. Quantum Measurement and Entanglement: Wave-Function
Collapse
* 13.1: Introduction
* 13.2: Quantum Measurement
* 13.3: Quantum Entanglement and the Impact of Measurement
* 13.4: Quantum Teleportation
* 13.5: Summary
* Chapter 14. Loss and Decoherence: The RLC Circuit
* 14.1: Introduction
* 14.2: Coupling to a Continuum of States: The Weisskopf-Wigner
Approximation
* 14.3: Decay in the Nano-Vibrator Problem
* 14.4: The RLC Circuit
* 14.5: Summary
* Chapter 15. The Quantum Radiation Field: Spontaneous Emission and
Entangled Photons
* 15.1: Introduction
* 15.2: Finding the Hamiltonian for the Transverse Electromagnetic
Field
* 15.3: Quantizing the Field
* 15.4: Spontaneous Emission
* 15.5: The Effects of the Quantum Vacuum on Linear Absorption and
Dispersion
* 15.6: Rabi Oscillations in the Vacuum: The Jaynes Cummings
Hamiltonian
* 15.7: Summary
* Chapter 16. Atomic Operators
* 16.1: Introduction
* 16.2: Defining the Atomic Operators
* 16.3: The Physical Meaning of the Atomic Operators
* 16.4: The Atomic Operators in the Heisenberg Picture
* 16.5: The Exact Solution for the Atomic Operators for a Monochromatic
Field
* 16.6: The Operator Equations of Motion Including Spontaneous Emission
* Chapter 17. Quantum Electromagneticst
* 17.1: Introduction
* 17.2: The Number State Representation
* 17.3: The Coherent State
* 17.4: Quantum Beam Splitter: Quantum Interference
* 17.5: Resonant Rayleigh Scattering: A Single Quantum Emitter
* 17.6: Creating a Quantum Entangled State Between a Photon and an
Electron
* 17.7: Engineering the Quantum Vacuum
* 17.8: Summary
* Chapter 18. The Density Matrix: Bloch Equations
* 18.1: Introduction
* 18.2: The Density Matrix Operator
* 18.3: The Density Matrix Equations Including Relaxation
* 18.4: Solving the Reduced Density Matrix for a Two-Level System in
the Presence of Resonant Classical Electromagnetic Field
* 18.5: Rate Equation Approximation
* 18.6: The Three-Level System: Emerging Importance in Quantum
Technology
* 18.7: Summary
* Appendices
* A: Essential Mathematics Review
* B: Power Series for important Functions
* C: Properties and Representations for the Dirac Delta Function
* D: Vector Calculus and Vector IdentifiesThe Electromagnetic
Hamiltonian and the Göpert-Mayer Transformation
* E: The Electromagnetic Hamiltonian and the Göpert-Mayer
Transformation
* F: Maxwell's Equations in Media, the Wave Equation and Coupling to a
two-level system
* G: Wigner-Eckart Theorem for evaluating matrix elements.