Electro Magnetic Waves
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General Learning Resources
Maxwell’s Equations:
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$\oint E \cdot d A=Q / \varepsilon_{0}$ (Gauss’s Law for electricity)
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$\oint \mathrm{B} \cdot \mathrm{dA}=0$ (Gauss’s Law for magnetism)
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$\oint \mathrm{E} \cdot \mathrm{d} \ell=\frac{-\mathrm{d} \Phi_{\mathrm{B}}}{\mathrm{dt}}$ (Faraday’s Law)
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$\oint B \cdot d \ell=\mu_{0} i_{c}+\mu_{0} \varepsilon_{0} \frac{d \Phi_{E}}{dt}$ (Ampere-Maxwell Law)
Oscillating Electric And Magnetic Fields:
$E=E_{x}(t)=E_{0} \sin (k z-\omega t)$
$=E_{0} \sin \left[2 \pi\left(\frac{z}{\lambda}-v t\right)\right]=E_{0} \sin \left[2 \pi\left(\frac{z}{\lambda}-\frac{t}{T}\right)\right]$
$E_{0} / B_{0}=c$
where:
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$c=1 / \sqrt{\mu_{0} \varepsilon_{0}} \quad c$ is speed of light in vacuum
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$v=1 / \sqrt{\mu \varepsilon} \quad v$ is speed of light in medium
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$p=\frac{U}{c}$ energy transferred to a surface in time $t$ is $U$, the magnitude of the total momentum delivered to this surface (for complete absorption) is $p$
Relation Between The Magnetic Field Vector And The Electric Field Vector:
$\vec{B} = \frac{1}{\omega}(\vec{k} \times \vec{E})$
Wave Velocity:
The relationship between the speed of light (c), the angular frequency $( \omega)$, and the wave number k: $c = \frac{\omega}{k}$
Poynting vector:
$\vec{S} = \frac{1}{c}(\vec{E} \times \vec{B})$
BETA
