Permeability and Permittivity of Free space

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The discussion centers on the physical interpretations of the constants ε₀ and μ₀, which relate to electric and magnetic fields, respectively. ε₀ is described as the ratio of electric charge to the electric field at a unit distance, derived from Coulomb's law and Gauss's law. In contrast, μ₀ represents the ratio of magnetic field to the enclosed current, as defined by Ampere's law. An analogy is drawn between electromagnetic waves and mechanical waves, suggesting that the constants reflect the tension and inertia of the medium through which they propagate. This exploration hints at the potential for a unified theory connecting these concepts.
metrictensor
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Does anyone know of a physical explanation of \epsilon_{0} and \mu_{0}?
 
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metrictensor said:
Does anyone know of a physical explanation of \epsilon_{0} and \mu_{0}?
I would say that:

a) \epsilon_0 is a measure of the ratio between electric charge and the electric field of the charge at a unit distance or the ratio of enclosed charge to flux at a unit distance (ie. through a sphere of radius 1 and area 4\pi)

\epsilon_0 = \frac{Q}{4\pi E} from the Coulomb force law.
\epsilon_0 = \frac{Q}{\oint E\cdot dA} = \frac{Q}{4\pi E} from Gauss' law

b) \mu_0 is a measure of the ratio between magnetic field and the enclosed current:

\mu_0 = \frac{\oint B\cdot ds}{I} from Ampere's law

For a conducting wire \mu_0 is the ratio of the magnetic field - at unit distance - to the current in the wire:

\mu_0 = \frac{2\pi B}{I}

AM
 
Hmm, also consider this interpretation. Mechanical waves (wave on a string) have a speed equal to sqrt(Tension/Inertia) where the tension and inertial terms reflect the tension and inertial properties of the medium the wave is traveling in.

EM waves have a speed equal to sqrt(1/e*m). Think of how e and m correspond with each other, specifically in Gauss's and Ampere's laws. 1/e corresponds to m, in other words.

So (1/em) = (1/e)/m = tension/ inertia.

Thus, 1/e corresponds to the tension of the medium (the higher the tension, the faster the string responds to a pluck. Maxwell himself talked about electric field lines being "under tension", stronger field = more tension).

Then m corresponds to inertia. This makes sense if you thing about an inductor, where the magnetic field opposes the change in current.

These analogies are nice, and it would be nice if you could create a grand unified theory from them. Thanks in advance ;)
 
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