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Basic principles of induction logging : electromagnetic methods in borehole geophysics /

Annotation

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Kaufman, Alexander A., 1931-2023
Otros Autores: Itskovich, Gregory
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Amsterdam : Elsevier, 2017.
Temas:
Acceso en línea:Texto completo

MARC

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100 1 |a Kaufman, Alexander A.,  |d 1931-2023. 
245 1 0 |a Basic principles of induction logging :  |b electromagnetic methods in borehole geophysics /  |c Alexander Kaufman, Gregory Itskovich. 
260 |a Amsterdam :  |b Elsevier,  |c 2017. 
300 |a 1 online resource (522 pages) 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
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505 0 |6 880-01  |a 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. 
505 8 |a 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. 
505 8 |a 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. 
505 8 |a 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. 
500 |a 3.1. Plane Wave in a Uniform Medium. 
588 0 |a Print version record. 
520 8 |a Annotation  |b Basic Principles of Induction Logging provides geoscientists with the information required to survey the electrical conductivity of rocks surrounding a borehole. The formation conductivity distribution in the borehole vicinity is critical information required in formation evaluation and geosteering applications. Developing a theory of EM logging and on understanding basic physics for both wireline and LWD logging tools, this reference furnishes valuable insights for development and use of EM techniques in practical logging applications. Basic Principles of Induction Logging will be vital for anyone attempting to investigate, invent, and develop the next generation of EM logging tools. It will provide information required to enable operation in more challenging environments such as logging while drilling, anisotropic and thinly laminated formations, high angle and horizontal wells. Provides a step-by-step approach to the theory of electromagnetic methods in borehole applications starting from the simplest modelsPresents theory on the subject that has been previously hard to find, making this a must have reference for anyone working in the fieldDelivers a much needed update on the latest analysis methods, modelling techniques, drilling environments, and probe configurations. 
650 0 |a Induction logging. 
650 6 |a Diagraphies par induction.  |0 (CaQQLa)201-0192053 
650 7 |a Induction logging  |2 fast  |0 (OCoLC)fst00970755 
700 1 |a Itskovich, Gregory. 
776 0 8 |i Print version:  |a Kaufman, Alex A.  |t Basic Principles of Induction Logging : Electromagnetic Methods in Borehole Geophysics.  |d Saint Louis : Elsevier Science, �2017  |z 9780128025833 
856 4 0 |u https://sciencedirect.uam.elogim.com/science/book/9780128025833  |z Texto completo 
880 8 |6 505-01/(S  |a 2.3.3. Nonuniform Medium2.3.4. Quasi-Stationary Field; 2.3.5. Behavior of Charge Density δ02; Example One; Example Two; 2.3.6. Surface Distribution of Charges; 2.3.7. Slowly Varying (Quasi-Stationary) Field; 2.4. Displacement Currents; 2.4.1. Second Source of the Magnetic Field; 2.4.2. Total Current and the Charge Conservation Principle; 2.4.3. Currents in the Circuit With a Capacitor; 2.5. Maxwell's Equations; 2.5.1. Introduction; 2.5.2. Maxwell's Equations; 2.5.3. Second Form of Maxwell's Equations; 2.5.4. Maxwell's Equations in a Piecewise Uniform Medium.