IBDP Physics Chapter 10 Notes

Engineering Physics Theory

STUDY NOTES FOR physics CHAPTER 10 – Engineering Physics Theory

These notes have specially been curated by expert teachers to simplify and enlighten concepts given in IBDP Physics HL and SL. The notes are comprehensive in nature and are sufficient to study the chapter in depth and one need not look for other resources beyond the notes provided on our website which can be accessed for free. The notes for Mechanics IBDP Physics are available on our official website and can be downloaded for free. You are one click away from obtaining all that you need to score well in IB Physics HL and SL.

The curriculum for Physics IBDP is designed in such a way to bring students and readers alike to the frontiers of modern science and elevate the spirit of scientific inquiry in their minds. The topics in the syllabus range from the ancient science of the Greeks to modern disciplines like Atomic and Astrophysics, which makes the students aware of the entire spectrum of the discoveries and advances in Physics alongside the rationale and its purpose. As such the chapters are divided by classical and modern distinctions: classical chapters include Newtonian Mechanics describe the original theories of motion and movement, Thermodynamics talk about our original assumptions of ideal gas and principles of heat and temperature, while Electrodynamics cover the interconnected universe of electricity, magnetism and electromagnetic waves, and the various properties and phenomena associated with them.

In contrast lies the topics of Modern Science, ranging from Atomic, Nuclear and Particle Physics to the more advanced study of motion in Einstein’s Relativity and Quantum Mechanics. A complete understanding of these topics will render any reader with the amazing ability to apply Physics to every corner of life, ranging from the mundane to the extraordinary; prepare them prepare them for only a future in an advanced scientific discipline, but also in fields like Economics, Finance and Technology, all of which require a scientific mindset at their core.

The curriculum for Physics IBDP is designed in such a way to bring students and readers alike to the frontiers of modern science and arouse the spirit of scientific inquiry in their minds. The topics in the syllabus range from the ancient science of the Greeks to modern disciplines like Atomic and Astrophysics, which makes the students aware of the entire spectrum of the discoveries and advances in Physics as well as the rationale and need behind them.

As such the chapters are divided by classical and modern distinctions: Newtonian Mechanics describe the original theories of motion and movement, Thermodynamics talk about our original assumptions of ideal gas and principles of heat and temperature, while Electrodynamics cover the interconnected universe of electricity, magnetism and electromagnetic waves, and the various properties and phenomena associated with them. In contrast lies the topics of Modern Science, ranging from Atomic, Nuclear and Particle Physics to the more advanced study of motion in Einstein’s Relativity and Quantum Mechanics.

A complete understanding of these topics will render any reader with the amazing ability to apply Physics to every corner of life, ranging from the mundane to the extraordinary; as well as assuredly prepare them not only for a future in an advanced scientific discipline, but also in fields like Economics, Finance and Technology, all of which require a scientific mindset at their core.

In this chapter of Engineering Physics, we begin with the study of rigid body motion and rotational dynamics, with rotational analogues of linear quantities like torque (force), moment of inertia (mass), angular momentum (linear momentum), and the corresponding Newton’s Laws. We move onto the laws of thermodynamics, different types of processes – isobaric, adiabatic, isothermal and isochoric, which constitute a cyclic process studied in the Carnot engine. Further, we illustrate Pascal’s and Archimedes’ Principle in static fluids, and the continuity equation, Bernoulli’s Principle and Stokes’ Law in dynamic fluids. Finally, we end the chapter with a discussion on damped and forced vibrations, and the phenomenon of resonance.