English | MP4 | AVC 1280×720 | AAC 44KHz 2ch | 48 Lessons (21h 0m) | 8.02 GB
Launch Your Career in Electrodynamics. The goal of Electrodynamics is to not only teach electromagnetism but also introduce some mathematical tools which can be used to solve problems in the subject.
What you’ll learn
If you want to apply electrodynamics to your materials research project, this Specialization will help you do so. Electromagnetic force is one of the fundamental forces that hold atoms and molecules together, which are the building blocks of any materials.In four courses, you will learn the foundations of electrodynamics starting from the nature of electrical force up to the level of in-depth solutions of Maxwell equations. We will walk you through vector calculus, concepts of field, flux and circulation, electrostatics, and magnetostatics as well as electrodynamics. By the end of this Specialization you will understand four beautiful equations organized by Maxwell in a full picture. Special relativity will be covered as well to grasp the idea that magnetism is a relativistic effect of electricity. The approach taken in this Specialization complements traditional approaches, covering a fairly complete treatment of the physics of electricity and magnetism, and adds Feynman’s unique and vital approach of grasping a whole picture of the physical universe. In addition, this Specialization uniquely bridges the gap between the knowledge of electrodynamics and its practical applications to research in materials science, information technology, electrical engineering, chemistry, chemical engineering, energy storage, energy harvesting, and other materials related fields.
Skills you’ll gain
- Electrical Systems
- Scientific Visualization
- Electrical Engineering
- Differential Equations
- Engineering Analysis
- Semiconductors
- Applied Mathematics
- Electronics
- Electronic Components
- Mechanics
- Advanced Mathematics
- Materials science
- Engineering Calculations
- Basic Electrical Systems
- Energy and Utilities
- Mathematical Modeling
- Integral Calculus
- Electronics Engineering
- Finite Element Methods
- Physics
If you want to apply electrodynamics to your materials research project, this Specialization will help you do so. Electromagnetic force is one of the fundamental forces that hold atoms and molecules together, which are the building blocks of any materials.In four courses, you will learn the foundations of electrodynamics starting from the nature of electrical force up to the level of in-depth solutions of Maxwell equations. We will walk you through vector calculus, concepts of field, flux and circulation, electrostatics, and magnetostatics as well as electrodynamics. By the end of this Specialization you will understand four beautiful equations organized by Maxwell in a full picture. Special relativity will be covered as well to grasp the idea that magnetism is a relativistic effect of electricity. The approach taken in this Specialization complements traditional approaches, covering a fairly complete treatment of the physics of electricity and magnetism, and adds Feynman’s unique and vital approach of grasping a whole picture of the physical universe. In addition, this Specialization uniquely bridges the gap between the knowledge of electrodynamics and its practical applications to research in materials science, information technology, electrical engineering, chemistry, chemical engineering, energy storage, energy harvesting, and other materials related fields.
Applied Learning Project
The purpose behind this particular project is learning to apply the concepts of Electrodynamics. Therefore, we ask you to apply the equations and concepts you learned designing or improving a process relating to your own work or a topic you are interested in.
You will have a chance to write a short paper on any research topic that uses the knowledge you learned in this Specialization. Through this project, you will learn hands on how to apply the electrodynamics in your current or future research.
Table of Contents
electrodynamics-analysis-of-electric-fields
the-electric-field-in-various-circumstances
introduction
1 introduction
2 values-of-physical-constants_instructions
electrostatic-potential-and-the-dipole-approximation
3 equations-of-the-electrostatic-potential
4 the-dipole-approximation-for-an-arbitrary-distribution
5 lecture-slides-week-1_instructions
the-electric-field-in-various-circumstances-cont-d
electrostatic-fields-and-colloidal-particles
6 finding-an-electrostatic-field
7 colloidal-particles-and-grid-fields
8 lecture-slides-week-2_instructions
electrostatic-energy
electrostatic-energy
9 energy-and-forces-associated-with-capacitors
10 energy-in-ionic-crystals-and-electrostatic-fields
11 lecture-slides-week-3_instructions
introduction-to-dielectrics
dielectric-constants-and-nonuniform-dielectrics
12 dielectric-constants-and-susceptibility
13 nonuniform-dielectrics-and-forces
14 lecture-slides-week-4_instructions
dielectrics-cont-d
dipoles-and-dielectrics-of-different-phases
15 electronic-polarization
16 the-electric-field-in-cavities-and-solid-dielectrics
17 lecture-slides-week-5_instructions
conclusion
18 summary
electrodynamics-electric-magnetic-fields
electrostatic-analogs
introduction
19 introduction
20 values-of-physical-constants_instructions
applying-electrodynamic-solutions-to-other-fields
21 modeling-heat-flow-and-membranes
22 different-spherical-solutions
23 lecture-slides-week-1_instructions
magnetostatics
introduction-to-magnetic-forces-and-fields
24 magnetic-fields-and-forces
25 interactions-with-magnetic-fields
26 lecture-slides-week-2_instructions
the-magnetic-field-in-various-situations
understanding-the-vector-potential
27 introduction-to-the-vector-potential
28 the-vector-potentials-for-specific-geometries
29 lecture-slides-week-3_instructions
assessing-the-vector-potential
mechanical-energy-and-quantum-mechanics
30 mechanical-and-electrical-energy
31 comparing-quantum-mechanics-and-dynamics
32 lecture-slides-week-4_instructions
induced-currents
motors-and-other-inventions
33 running-motors
34 forces-from-induced-currents
35 lecture-slides-week-5_instructions
conclusion
36 conclusion
electrodynamics-introduction
introduction-and-basics-of-electrostatics
intro
37 introduction
38 values-of-physical-constants_instructions
introduction-to-electromagnetism-and-electrodynamic-equations
39 introduction-to-electromagnetism
40 introduction-to-electrodynamic-equations
41 lecture-slides-week-1_instructions
introduction-to-differential-calculus-of-vector-fields
scalars-vectors-and-the-operator
42 scalars-and-vectors
43 applying-the-operator
44 lecture-slides-week-2_instructions
introduction-to-vector-integral-calculus
gauss-theorem-flow-and-circulation
45 deriving-gauss-theorem
46 flow-and-circulation
47 lecture-slides-week-3_instructions
introduction-to-electrostatic-solutions
electrostatics-and-flux-of-electric-potential
48 electrostatics-and-electric-potential
49 the-flux-of-an-electric-potential
50 lecture-slides-week-4_instructions
the-application-of-gauss-law
electrostatic-fields-and-shielding
51 electrostatic-fields
52 fields-inside-of-shells
53 lecture-slides-week-5_instructions
conclusion
54 summary
electrodynamics-solutions-maxwells-equations
the-laws-of-induction
introduction
55 introduction
56 values-of-physical-constants_instructions
the-laws-of-induction
57 induction-and-electromotive-forces
58 alternating-current-generators-and-mutual-inductance
59 lecture-slides-week-1_instructions
the-maxwell-equations
the-maxwell-equations
60 a-review-of-classical-physics
61 analyzing-traveling-fields
62 lecture-slides-week-2_instructions
maxwells-equations-in-free-space
maxwells-equations-in-free-space
63 equations-which-satisfy-the-wave-equation
64 solutions-for-the-wave-equation
65 lecture-slides-week-3_instructions
maxwells-equations-with-currents-and-charges
maxwells-equations-with-currents-and-charges
66 an-introduction-to-moving-charges
67 relativistic-corrections
68 lecture-slides-week-4_instructions
introduction-to-alternating-circuits
introduction-to-alternating-circuits
69
70 energy-loss-and-complex-circuit-design
71 lecture-slides-week-5_instructions
conclusion
72 summary
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