Physics 180 Lecture Series
This is going to be the section which will cover Physics 180 - Newtonian Mechanics. This is the physics of the macroscopic world, the world that most of us can see, touch, hear, taste, and smell. Most physics define Newtonian Physics as the physics which has been discovered by 1900, but this feels too arbitrary for me. The reason why it's the physics which has been discovered by 1900 is because we as a species have discovered the entirety of the physics of the macroscopic world by 1900, while the rest of physics (waves mechanics, Relativity, Quantum Physics, etc.) has yet to be discovered by this year. With that in mind, while the "discovered by 1900" is an accurate definition as a time separator between the Newtonian and non-Newtonian classes, I still prefer the physical definition over the discovery date definition.
When I speak of the physics of the macroscopic world, I am speaking of the motions of these objects and the energy and forces associated with those motions, and the mathematics which goes along with those motions, energies, and forces. It sounds simple enough, but it can get very complicated very quickly. Fair warning, this is the Calculus-based Newtonian Mechanics course, so it is better for a conceptual understanding of the material to have some kind of calculus background. It doesn't have to be much for this lecture series, but it should be present.
The book I will be referencing will be Physics for Scientists and Engineers 7th Edition by Raymon Serway and John Jewett, so if you want to follow along, you can. The sections will be linked to their corresponding blog once that blog has been posted. The chapters covered in this lecture series is listed here:
K. "Alan" Eister, -Δαβ
To help get this lecture series come out with higher frequency, please donate to The Science of Life. This helps keep the information current and allows me to dedicate more time to this project instead of obtaining money through external means.
- Chapter 1: Physics and Measurements
- Chapter 3: Vectorsctor and Unit Vectors
- Chapter 2: Motion in One-Dimension
- Chapter 4: Motion in Two-Dimensions
- Chapter 5: The Laws of Motion
- Chapter 6: Circular Motion and Other Applications of Newton's Laws
- Chapter 7: Energy of a System
- Chapter 8: Conservation of Energy
- Chapter 9: Linear Momentum and Collisions
- Chapter 10: Rotation of a Rigid Object About a Fixed Axis
- Chapter 11: Angular Momentum
- Chapter 12: Static Equilibrium and Elasticity
- Chapter 13: Universal Gravitation
K. "Alan" Eister, -Δαβ
To help get this lecture series come out with higher frequency, please donate to The Science of Life. This helps keep the information current and allows me to dedicate more time to this project instead of obtaining money through external means.
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