Applied Physics For Engineering III - Modern Physics

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Free Download Applied Physics For Engineering III - Modern Physics
Published: 3/2025
Created by: Pedro Portugal
MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz, 2 Ch
Level: Intermediate | Genre: eLearning | Language: English | Duration: 25 Lectures ( 4h 49m ) | Size: 2.22 GB

Modern Physics for Engineering: Electromagnetism, Quantum Mechanics, and Relativity in Technology
What you'll learn
Understand Maxwell's equations in electromagnetic systems and their engineering applications
Explain the principles of special relativity and their implications for modern technology and high-speed systems.
Analyze quantum mechanical concepts and their relevance to advanced materials and nanoscale engineering.
Examine the principles of relativity and their practical applications in technology, such as GPS systems and high-energy particle accelerators.
Requirements
B.S or graduate students, Mechanical engineering, Manufacturing Engineering, Aerospace Engineering, Electronics Engineering, Physics, Technicians with industry experience.
Description
This course explores the fundamental principles of modern physics and their direct applications in engineering and technology. Divided into four modules, it provides a foundational understanding of electromagnetism, relativity, quantum mechanics, and their role in cutting edge innovations.The first module focuses on electromagnetism, beginning with Maxwell's equations, which describe the behavior of electric and magnetic fields. Students will explore electromagnetic waves, their properties, and practical applications, including electric motors, inductive charging, etc.The second module covers relativity, starting with Einstein's postulates and the Lorentz transformations. Topics such as time dilation, length contraction, relativistic energy, and the curvature of spacetime will be examined, highlighting their relevance in technologies like GPS and particle accelerators.The third module introduces quantum mechanics, discussing foundational concepts such as wave-particle duality, the Schrödinger equation, quantum superposition, and tunneling effects. These principles are key to understanding nanoscale systems, quantum computing, and advanced materials like superconductors.The final module connects these concepts to real world applications, exploring how modern physics enables advancements in communication, material science, and energy systems. Topics include photonics in data transmission, graphene and superconductors in electronics, and nuclear physics in energy production and medical imaging.By the end of this course, students will develop a strong theoretical foundation in modern physics while gaining insight into its technological implications. Through a case study, they will learn to analyze and apply these principles to real world engineering challenges.
Who this course is for
Engineers, senior or grad students. Entrepreneurs and Innovators, designers, manufacturing professionals (with our without a college degree). Overall, Professionals Seeking Career Growth
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Applied Physics For Engineering Iii: Modern Physics
Published 3/2025
MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
Language: English | Size: 2.07 GB | Duration: 4h 48m​

Modern Physics for Engineering: Electromagnetism, Quantum Mechanics, and Relativity in Technology

What you'll learn

Understand Maxwell's equations in electromagnetic systems and their engineering applications

Explain the principles of special relativity and their implications for modern technology and high-speed systems.

Analyze quantum mechanical concepts and their relevance to advanced materials and nanoscale engineering.

Examine the principles of relativity and their practical applications in technology, such as GPS systems and high-energy particle accelerators.

Requirements

B.S or graduate students, Mechanical engineering, Manufacturing Engineering, Aerospace Engineering, Electronics Engineering, Physics, Technicians with industry experience.

Description

This course explores the fundamental principles of modern physics and their direct applications in engineering and technology. Divided into four modules, it provides a foundational understanding of electromagnetism, relativity, quantum mechanics, and their role in cutting edge innovations.The first module focuses on electromagnetism, beginning with Maxwell's equations, which describe the behavior of electric and magnetic fields. Students will explore electromagnetic waves, their properties, and practical applications, including electric motors, inductive charging, etc.The second module covers relativity, starting with Einstein's postulates and the Lorentz transformations. Topics such as time dilation, length contraction, relativistic energy, and the curvature of spacetime will be examined, highlighting their relevance in technologies like GPS and particle accelerators.The third module introduces quantum mechanics, discussing foundational concepts such as wave-particle duality, the Schrödinger equation, quantum superposition, and tunneling effects. These principles are key to understanding nanoscale systems, quantum computing, and advanced materials like superconductors.The final module connects these concepts to real world applications, exploring how modern physics enables advancements in communication, material science, and energy systems. Topics include photonics in data transmission, graphene and superconductors in electronics, and nuclear physics in energy production and medical imaging.By the end of this course, students will develop a strong theoretical foundation in modern physics while gaining insight into its technological implications. Through a case study, they will learn to analyze and apply these principles to real world engineering challenges.

Overview

Section 1: Introduction

Lecture 1 Introduction

Lecture 2 Course Structure & Syllabus

Lecture 3 Specialization Options

Section 2: Electromagnetism and Optics in Engineering

Lecture 4 Introduction to Maxwell's Equations

Lecture 5 Gauss's Law for Electricity

Lecture 6 Gauss's Law for Magnetism

Lecture 7 Faraday's Law of Induction

Lecture 8 Ampère's Law with Maxwell's Correction

Lecture 9 Electromagnetic Waves and Their Properties

Lecture 10 Fundamentals of Optics: Reflection, Refraction, and Diffraction

Lecture 11 Optical Devices and Engineering Applications

Lecture 12 Maxwell's equations Exercise

Section 3: Relativity and Its Engineering Implications

Lecture 13 Foundations of Special Relativity: Postulates and Transformations

Lecture 14 Time Dilation and Length Contraction

Lecture 15 Relativistic Energy and Momentum in High-Speed Applications

Lecture 16 General Relativity: Gravity as Spacetime Curvature

Section 4: Quantum Mechanics for Engineering and Technology

Lecture 17 Introduction to Quantum Mechanics: Wave-Particle Duality and Uncertainty

Lecture 18 Schrödinger's Equation and Its Physical Interpretations

Lecture 19 Quantum States and Superposition in Nanoscale Systems

Lecture 20 Quantum Tunneling and Its Engineering Applications

Section 5: Practical Applications of Modern Physics

Lecture 21 Applications of Electromagnetism in Engineering: Examining electric motors and i

Lecture 22 Optical Technologies: Utilizing principles of reflection and refraction in fiber

Lecture 23 Relativity in Modern Technologies: Understanding time dilation in GPS technology

Lecture 24 Quantum Mechanics in Material Science: Investigating superconductors and graphen

Section 6: Closing

Lecture 25 Closing

Engineers, senior or grad students. Entrepreneurs and Innovators, designers, manufacturing professionals (with our without a college degree). Overall, Professionals Seeking Career Growth

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