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Physical (wave) optics
Page 1 of 2 DAVID LIAO.COM
Light can be described as a wave - In vacuum, a sinusoidal wave train of light consists of a sinusoidal electric field wave train and a sinusoidal magnetic field wave train. The electric and magnetic field waves are transverse (axes of oscillation perpendicular to direction of propagation), and the electric and magnetic field oscillations are perpendicular to each other. The axis of polarization of light is the axis of polarization of the electric field. Speed of light in vacuum β The speed of propagation through a vacuum for both the electric field wave and the magnetic field wave is called ππ.
ππ = 3.00 Γ 108 ms
Brightness β Amplitude corresponds to intensity, and increasing intensity corresponds to increasing brightness.
πΌπΌ β π΄π΄2
β amplitude ββ brightness
Color - Frequency and (associated vacuum) wavelength correspond to color.
Just as has been the case for other waves we have encountered in AP Physics, frequency and wavelength are inversely proportional.
ππ = ππππ
Physical (wave) optics
Page 2 of 2 DAVID LIAO.COM
Double-slit interference
For small angle ππ (π₯π₯ βͺ πΏπΏ),
Bright maxima
Dark minima
ππππππ β sinππ β
π₯π₯πΏπΏ
ππ = 0,1,2, β¦
οΏ½ππ β12οΏ½
ππππ β sinππ β
π₯π₯πΏπΏ
ππ = 1,2,3, β¦
Single-aperture interference
For small angle ππ (π₯π₯ βͺ πΏπΏ),
Bright maxima (except central maximum)
Dark minima
οΏ½ππ +12οΏ½
ππππ β sinππ β
π₯π₯πΏπΏ
ππ = 1,2,3, β¦
ππππππ β sinππ β
π₯π₯πΏπΏ
ππ = 1,2,3, β¦
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