introduction to electrodynamics ( PDFDrive ).pdf
4.6 MB
Introduction to electrodynamics by David Griffiths. Often referred to as the bible of electromagnetism🔥
#Griffiths #Electrodynamics #Physics #Books
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#Griffiths #Electrodynamics #Physics #Books
@EnochsRealm
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I honestly haven't came across an intro to electrodynamics book that can be compared to this, so that's all I have for electrodynamics :)
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But wait, let's not rush, we have Zangwill and Jackson on a more advanced level but are written very neatly and they are an absolute masterpieces.
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Classical_Electrodynamics_by_John_David.pdf
56.4 MB
Classical electrodynamics by Jackson.
Its advanced and is more often used in Graduate classes.
#Jackson #Electrodynamics #Books
@EnochsRealm
Its advanced and is more often used in Graduate classes.
#Jackson #Electrodynamics #Books
@EnochsRealm
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Quantum mechanics is the branch of physics that deals with the behavior of very tiny things, like atoms and subatomic particles. Unlike our everyday experience, where objects follow predictable paths (like a ball thrown through the air), particles in the quantum world behave in strange and surprising ways.
For example, in quantum mechanics:
Quantum mechanics helps us understand and predict how the fundamental particles of the universe interact with each other, which is crucial for technologies like semiconductors, lasers, and even MRI machines.
#QuantumPhysics
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For example, in quantum mechanics:
Particles can be in two places at once: A particle like an electron doesn’t have a definite position until we measure it. Before we measure, it can be thought of as being in multiple places at once, a concept called "superposition."
Particles behave both like particles and waves: An electron, for instance, can act like a tiny ball (a particle) or like a wave, depending on how we observe it. This dual nature is called "wave-particle duality."
Observing something changes it: Just by observing or measuring a quantum particle, we change its behavior. This is known as the "observer effect."
Uncertainty rules: We can’t know everything about a particle at the same time. For example, the more accurately we know a particle’s position, the less accurately we can know its speed, and vice versa. This is known as the "uncertainty principle."
Quantum mechanics helps us understand and predict how the fundamental particles of the universe interact with each other, which is crucial for technologies like semiconductors, lasers, and even MRI machines.
#QuantumPhysics
@EnochsRealm
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