How did Maxwell find the speed of light

AI Thread Summary
Maxwell derived the speed of light by calculating it from electromagnetic wave equations, specifically using Coulomb's constant and the magnetic constant, leading to the formula √(Ke/μ0). This calculation yielded a speed of approximately 3 x 10^8 m/s, which matched the previously measured speed of light. The connection between these constants and the speed of light is rooted in the fundamental properties of electromagnetic waves as described by Maxwell's equations. Although the math involves complex vector calculus, the result is consistent with experimental measurements of light's speed. Maxwell's insight that these waves were indeed light was a significant leap in understanding electromagnetic theory.
stephen8686
Messages
42
Reaction score
5
According to this video I was watching Maxwell was looking for the speed of EM waves and just divided coulomb's constant by the magnetic constant and then took the square root and that was the speed of light.

√(Ke0)=√(9e9/1e-7) = 3e8m/s

So why is this a thing? I just don't understand why it works, and how did Maxwell know it was the speed of light?
 
Physics news on Phys.org
Which video? Until you tell us that, we don't know whether it's incomplete or whether you're missing something.

One of the solutions to Maxwell's equations is an electromagnetic wave moving at ##3\times{10}^8## m/sec; you will find some good derivations if you google for "Maxwell speed of light derivation". However they will require some vector calculus and solving a differential equation so I don't know if there's a better answer than "Trust us, that's what you get when you do the math" without understanding the math.

The speed of light had been measured and found to be ##3\times{10}^8## m/sec long before anyone had any idea what light was. So when Maxwell worked through the math and found that it predicted waves traveling at the already known speed of light he made an inspired guess - that the waves his equation predicted were light.
 
Nugatory said:
Which video? Until you tell us that, we don't know whether it's incomplete or whether you're missing something.

One of the solutions to Maxwell's equations is an electromagnetic wave moving at ##3\times{10}^8## m/sec; you will find some good derivations if you google for "Maxwell speed of light derivation". However they will require some vector calculus and solving a differential equation so I don't know if there's a better answer than "Trust us, that's what you get when you do the math" without understanding the math.

The speed of light had been measured and found to be ##3\times{10}^8## m/sec long before anyone had any idea what light was. So when Maxwell worked through the math and found that it predicted waves traveling at the already known speed of light he made an inspired guess - that the waves his equation predicted were light.

The video is here:
The part that I am referring to happens at about 11;30
It's a pretty simple video, so I don't think I am missing anything, and the video is on caltech's channel so I assume it is credible. I see that the speed of light can be determined from Ampere's Law (which I will not fully understand until the end of this year). I just don't understand why these two particular constants have any relationship to the speed of light.
 

Thread 'Maxwell stress tensor'

This is from Griffiths' Electrodynamics, 3rd edition, page 352. I am trying to calculate the divergence of the Maxwell stress tensor. The tensor is given as ##T_{ij} =\epsilon_0 (E_iE_j-\frac 1 2 \delta_{ij} E^2)+\frac 1 {\mu_0}(B_iB_j-\frac 1 2 \delta_{ij} B^2)##. To make things easier, I just want to focus on the part with the electrical field, i.e. I want to find the divergence of ##E_{ij}=E_iE_j-\frac 1 2 \delta_{ij}E^2##. In matrix form, this tensor should look like this...
View full post »
Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Thread 'Applying the Gauss (1835) formula for force between 2 parallel DC currents'

Please can anyone either:- (1) point me to a derivation of the perpendicular force (Fy) between two very long parallel wires carrying steady currents utilising the formula of Gauss for the force F along the line r between 2 charges? Or alternatively (2) point out where I have gone wrong in my method? I am having problems with calculating the direction and magnitude of the force as expected from modern (Biot-Savart-Maxwell-Lorentz) formula. Here is my method and results so far:- This...
View full post »

Similar threads

Maxwell's calculations on electromagnetism's speed = light speed
Replies
15
Views
4K
Maxwell and the speed of light
Replies
9
Views
2K
Maxwell distributions and average, RMS, and most probable speeds
Replies
3
Views
2K
Macroscopic Maxwell's equations and speed of light in media
Replies
6
Views
2K
How did Maxwell's theory predict that c is constant?
Replies
12
Views
3K
How do we know electromagnetic waves are light?
Replies
42
Views
5K
I Gravity Wave Speed: Deriving Constancy from Maxwell Eqs.
Replies
34
Views
2K
In what year was proposed that light is an electromagnetic wave?
Replies
3
Views
4K
B Interpreting light as Maxwell's EM wave
2
Replies
65
Views
5K
How Fast Does an Electrical Impulse Travel in a Copper Wire?
3
Replies
100
Views
10K

Hot Threads

Recent Insights

Back
Top