Scalar Wave Driven Energy Applications

Chapter 1:Foundation of Electromagnetic Theory1.1Introduction1.2Vector Analysis1.2.1Vector Algebra1.2.2Vector Gradient1.2.3Vector Integration1.2.4Vector Divergence1.2.5Vector Curl1.2.6Vector Differential Operator1.3Further Developments1.4Electrostatics1.4.1The Coulomb's Law1.4.2The Electric Field1.4.3The Gauss's Law1.5Solution of Electrostatic Problems1.5.1Poisson's Equation1.5.2Laplace's Equation1.6Electrostatic Energy1.6.1Potential Energy of a Group of Point Charges1.6.2Electrostatic Energy of a Charge Distribution1.6.3Forces and Torques1.7Maxwell's Equations Descriptions1.8Time-Independent Maxwell Equations1.8.1Coulomb's Law1.8.2The Electric Scalar Potential1.8.3Gauss's Law1.8.4Poisson's Equation1.8.5Ampere's Experiments1.8.6The Lorentz Force1.8.7Ampere's Law1.8.8Magnetic Monopoles1.8.9Ampere's Circuital Law1.8.10Helmholtz's Theorem1.8.11The Magnetic Vector Potential1.8.12The Biot-Savart Law1.8.13Electrostatics and Magnetostatics1.9Time-Dependent Maxwell Equations1.9.1Faraday's Law1.9.2Electric Scalar Potential1.9.3Gauge Transformations1.9.4The Displacement Current1.9.5Potential Formulation1.9.6Electromagnetic Waves1.9.7Green's Functions1.9.8Retarded Potentials1.9.9Advanced Potentials1.9.10Retarded Fields1.9.11Summary1.10ReferencesChapter 2:Maxwell's Equations - The Generalization of Ampere-Maxwell's Law2.1Introduction2.2The Permeability of Free Space µ02.3The Generalization of Ampere's Law with Displacement Current2.4The Electromagnetic Induction2.5The Electromagnetic Energy and Poynting Vector2.6Simple Classical Mechanics Systems and Fields2.7Lagrangian and Hamiltonian of Relativistic Mechanics2.7.1Four-Dimensional Velocity2.7.2Energy and Momentum in Relativistic Mechanics2.8Lorentz vs. Galilean Transformation2.9The Structure of Spacetime, Interval, and Diagram2.9.1Space-Time or Minkowski Diagram2.9.2Time Dilation2.9.3Time Interval2.9.4The Invariant Interval2.9.5Lorentz Contraction Length2.10ReferencesChapter 3:All About Wave Equations3.1Introduction3.2The Classical Wave Equation and Separation of Variables3.3Standing Waves3.4Seiche wave3.4.1Lake Seiche3.4.2See and Bay Seiche3.5Underwater or Internal Waves3.6Maxwell's Equations and Electromagnetic Waves3.7Scalar and Vector Potentials3.8Gauge Transformations, Lorentz Gauge, and Coulomb Gauge3.9Infrastructure, Characteristic, Derivation, and Properties of Scalar Waves3.9.1Derivation of the Scalar Waves3.9.2Wave Energy3.9.3The Particles or Charge Field Expression3.9.4Particle Energy3.9.5Velocity3.9.6The Magnetic Field3.9.7The Scalar Field3.9.8Scalar Fields, from Classical Electromagnetism to Quantum Mechanics3.9.8.1Scalar Interactions3.9.8.2Quantum Gauge Invariance3.9.8.3Gauge Invariant Phase Difference3.9.8.4The Matrix of Space-Time3.9.9Our Body Works with Scalar Waves3.9.10Scalar Waves Superweapon Conspiracy Theory3.9.11Deployment of Superweapon Scalar Wave Drive by Interferometer Paradigm3.9.11.1Wireless Transmission of Energy at a Distance Driven by Interferometry3.10The Quantum Waves3.11The X-Waves3.12The Nonlinear X-Waves3.13The Bessel's Waves3.14Generalized Solution to Wave Equation3.14ReferencesChapter 4:The Fundamental of Electrodynamics4.1Introduction4.2Maxwell's Equations and Electric Field of the Electromagnetic Wave4.3The Wave Equations for Electric and Magnetic Field4.4Sinusoidal Waves4.5Polarization of the Wave4.6Monochromatic Plane Waves4.7Boundary Conditions: Reflection & Transmission (Refraction) Dielectric Interface4.8Electromagnetic Waves in Matter4.8.1Propagation in Linear Media4.8.2Reflection and Transmission at Normal Incidence4.8.3Reflection and Transmission at Oblique Incidence4.9Absorption and Dispersion4.9.1Electromagnetic Waves in Conductors4.9.2Reflection at a Conducting Surface4.9.3The Frequency Dependence of Permittivity4.10Electromagnetic Waves in Conductors4.11ReferencesChapter 5:Deriving Lagrangian Density of Electromagnetic Field5.1Introduction5.2How the Field Transform5.3The Field Tensor5.4The Electromagnetic Field Tensor5.5The Lagrangian and Hamiltonian For Electromagnetic Fields5.6Introduction to Lagrangian Density5.7The Euler-Lagrange Equation of Electromagnetic Field5.7.1Error-Trial-Final Success5.8The Formal Structure of Maxwell's Theory5.9ReferencesChapter 6:Scalar Waves6.1Introduction6.2Transverse and Longitudinal Waves Descriptions6.2.1Pressure Waves and More Details6.2.2What are Scalar Longitudinal Waves6.2.2Scalar Longitudinal Waves Applications6.3Description of   Field6.4Scalar Wave Description6.5Longitudinal Potential Waves6.6Transmitters and Receiver for Longitudinal Waves6.6.1Scalar Communication System6.7Scalar Waves Experiments6.7.1Tesla Radiation6.7.2Vortex Model6.7.2.1Resonant Circuit Interpretation6.7.2.2Near Field Interpretation6.7.2.3Vortex Interpretation6.7.4Experiment6.7.5Summary6.7ReferencesAppendix A:Relativity and ElectromagnetismA.1IntroductionA.2The Formal Structure of Maxwell's TheoryA.3ReferencesAppendix B:Schrödinger Wave EquationB.1IntroductionB.2Schrödinger Equation ConceptB.3The Time-Dependent Schrödinger Equation ConceptB.4Time-Independent Schrödinger Equation ConceptB.5A Free Particle inside a Box and Density of StateB.6Relativistic Spin Zero Parties: Klein-Gordon EquationB.6.1AntiparticlesB.6.2Negative Energy States and AntiparticlesB.6.3Neutral ParticlesB.6ReferencesAppendix C:Four Vectors and Lorentz TransformationC.1IntroductionC.2Lorentz Transformation Factor DerivationC.3Mathematical Properties of the Lorentz TransformationC.4Cherenkov RadiationC.4.1Arbitrary Cherenkov Emission AngleC.4.2Reverse Cherenkov EffectC.4.3Cherenkov Radiation CharacteristicsC.4.4Cherenkov Radiation ApplicationsC.5Vacuum Cherenkov RadiationC.6Lorentz Invariance and Four-VectorsC.7Transformation Laws for VelocitiesC.8Faster Than Speed of LightC.7ReferencesAppendix D:Vector DerivativesD.1ReferencesAppendix E:Second Order Vector DerivativesE.1ReferencesIndex