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Basic principles of induction logging : electromagnetic methods in borehole geophysics / Alexander Kaufman, Gregory Itskovich.

By: Contributor(s): 2017Description: 1 online resource (522 pages)Content type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9780128025840
  • 0128025840
Subject(s): Genre/Form: Additional physical formats: Print version:: Basic Principles of Induction Logging : Electromagnetic Methods in Borehole Geophysics.LOC classification:
  • TN269.55
Online resources:
Contents:
Front Cover; Basic Principles of Induction Logging: Electromagnetic Methods in Borehole Geophysics; Copyright; Dedication; Contents; Introduction; Acknowledgments; List of Symbols; Chapter One: System of Equations of the Stationary Electric and Magnetic Fields; 1.1. Equations of the Stationary Electric Field in a Conducting and Polarizable Medium; 1.2. Interaction of Currents, Biot-Savart Law, and Magnetic Field; 1.2.1. Ampere's Law and Interaction of Currents; 1.2.2. Magnetic Field and Biot-Savart Law; 1.2.3. Lorentz Force and Electromotive Force Acting on the Moving Circuit; Example One.
Example TwoExample Three; Example Four; Example Five; 1.3. Vector Potential of the Magnetic Field; 1.3.1. Relation Between Magnetic Field and Vector Potential; 1.3.2. Divergence and Laplacian of Vector Potential; 1.4. System of Equations of the Stationary Magnetic Field; 1.5. Examples of Magnetic Field of Current-Carrying Objects; 1.5.1. Example One: Magnetic Field of the Current Filament; 1.5.2. Example Two: The Vector Potential A and the Magnetic Field B of a Current in a Circular Loop; 1.5.3. Example Three: Magnetic Fields of the Magnetic Dipole; Some Comments.
1.5.4. Example Four: Magnetic Field Due to a Current in a Cylindrical Conductor1.5.5. Example Five: Magnetic Field of Infinitely Long Solenoid; 1.5.6. Example Six: Magnetic Field of a Current Toroid; 1.6. System of Equations for the Stationary Fields; References; Further Reading; Chapter Two: Physical Laws and Maxwell's Equations; 2.1. Faraday's Law; 2.2. Principle of Charge Conservation; Case One: The Stationary Field; Case Two: Quasi-Stationary Electromagnetic Field; 2.3. Distribution of Electric Charges; 2.3.1. Equation for the Volume Charge Density; 2.3.2. Uniform Medium.
2.6. Equations for the Fields E and B2.7. Electromagnetic Potentials; 2.8. Maxwell's Equations for Sinusoidal Fields; 2.9. Electromagnetic Energy and Poynting Vector; 2.9.1. Principle of Energy Conservation and Joule's Law; 2.9.2. Energy Density and Poynting Vector; 2.9.3. Current Circuit and Transmission Line; 2.10. Uniqueness of the Forward Problem Solution; 2.10.1. Uniqueness Theorem; Case One; Case Two; 2.10.2. Formulation of the Boundary Value Problem; Reference; Further Reading; Chapter Three: Propagation of Electromagnetic Field in a Nonconducting Medium.
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880-01 Front Cover; Basic Principles of Induction Logging: Electromagnetic Methods in Borehole Geophysics; Copyright; Dedication; Contents; Introduction; Acknowledgments; List of Symbols; Chapter One: System of Equations of the Stationary Electric and Magnetic Fields; 1.1. Equations of the Stationary Electric Field in a Conducting and Polarizable Medium; 1.2. Interaction of Currents, Biot-Savart Law, and Magnetic Field; 1.2.1. Ampere's Law and Interaction of Currents; 1.2.2. Magnetic Field and Biot-Savart Law; 1.2.3. Lorentz Force and Electromotive Force Acting on the Moving Circuit; Example One.

Example TwoExample Three; Example Four; Example Five; 1.3. Vector Potential of the Magnetic Field; 1.3.1. Relation Between Magnetic Field and Vector Potential; 1.3.2. Divergence and Laplacian of Vector Potential; 1.4. System of Equations of the Stationary Magnetic Field; 1.5. Examples of Magnetic Field of Current-Carrying Objects; 1.5.1. Example One: Magnetic Field of the Current Filament; 1.5.2. Example Two: The Vector Potential A and the Magnetic Field B of a Current in a Circular Loop; 1.5.3. Example Three: Magnetic Fields of the Magnetic Dipole; Some Comments.

1.5.4. Example Four: Magnetic Field Due to a Current in a Cylindrical Conductor1.5.5. Example Five: Magnetic Field of Infinitely Long Solenoid; 1.5.6. Example Six: Magnetic Field of a Current Toroid; 1.6. System of Equations for the Stationary Fields; References; Further Reading; Chapter Two: Physical Laws and Maxwell's Equations; 2.1. Faraday's Law; 2.2. Principle of Charge Conservation; Case One: The Stationary Field; Case Two: Quasi-Stationary Electromagnetic Field; 2.3. Distribution of Electric Charges; 2.3.1. Equation for the Volume Charge Density; 2.3.2. Uniform Medium.

2.6. Equations for the Fields E and B2.7. Electromagnetic Potentials; 2.8. Maxwell's Equations for Sinusoidal Fields; 2.9. Electromagnetic Energy and Poynting Vector; 2.9.1. Principle of Energy Conservation and Joule's Law; 2.9.2. Energy Density and Poynting Vector; 2.9.3. Current Circuit and Transmission Line; 2.10. Uniqueness of the Forward Problem Solution; 2.10.1. Uniqueness Theorem; Case One; Case Two; 2.10.2. Formulation of the Boundary Value Problem; Reference; Further Reading; Chapter Three: Propagation of Electromagnetic Field in a Nonconducting Medium.

3.1. Plane Wave in a Uniform Medium.

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