PlanetPhysics/Derivation of Wave Equation From Maxwell's Equations

Maxwell was the first to note that Amp\`ere's Law does not satisfy conservation of [[../Charge/|charge]] (his corrected form is given in [[../MaxwellsEquations/|Maxwell's equation]]). This can be shown using the equation of conservation of electric charge:

$\nabla \cdot 𝐉 + \frac{\partial ρ}{\partial t} = 0$

Now consider Faraday's Law in differential form:

$\nabla \times 𝐄 = - \frac{\partial 𝐁}{\partial t}$

Taking the [[../Curl/|curl]] of both sides:

$\nabla \times (\nabla \times 𝐄) = \nabla \times (- \frac{\partial 𝐁}{\partial t})$

The right-hand side may be simplified by noting that

$\nabla \times (\frac{\partial 𝐁}{\partial t}) = - \frac{\partial}{\partial t} (\nabla \times 𝐁)$

Recalling Amp\`ere's Law,

$- \frac{\partial}{\partial t} (\nabla \times 𝐁) = - μ_{0} ϵ_{0} \frac{\partial^{2} 𝐄}{\partial t^{2}}$

Therefore

$\nabla \times (\nabla \times 𝐄) = - μ_{0} ϵ_{0} \frac{\partial^{2} 𝐄}{\partial t^{2}}$

The left hand side may be simplified by the following [[../VectorRelationships/|Vector Identity]]:

$\nabla \times (\nabla \times 𝐄) = - \nabla^{2} 𝐄$

Hence

$\nabla^{2} 𝐄 = μ_{0} ϵ_{0} \frac{\partial^{2} 𝐄}{\partial t^{2}}$

Applying the same analysis to Amp\'ere's Law then substituting in Faraday's Law leads to the result

$\nabla^{2} 𝐁 = μ_{0} ϵ_{0} \frac{\partial^{2} 𝐄}{\partial t^{2}}$

Making the substitution $μ_{0} ϵ_{0} = 1 / c^{2}$ we note that these equations take the form of a transverse [[../CosmologicalConstant2/|wave]] travelling at constant [[../Velocity/|speed]] $c$ . Maxwell evaluated the constants $μ_{0}$ and $ϵ_{0}$ according to their known values at the time and concluded that $c$ was approximately equal to 310,740,000 ${ms}^{- 1}$ , a value within ~3\

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PlanetPhysics/Derivation of Wave Equation From Maxwell's Equations

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