The Skin Effect in AC Circuits

AI Thread Summary
In DC circuits, charge carriers move uniformly across the wire's entire cross-section, while in AC circuits, they are confined to a thin "skin" layer just beneath the surface, reducing the effective cross-sectional area. This skin effect intensifies with higher frequencies due to the diffusion of current into the conductor's interior, where it decays exponentially. The presence of azimuthal magnetic fields generated by AC currents creates opposing eddy currents, which push the primary current towards the conductor's outer edge. The effective AC resistance can be calculated using the skin depth, which is influenced by the conductor's resistivity and geometry. The skin effect is discussed in detail in Smythe's "Static and Dynamic Electricity," highlighting its significance in electrical engineering.
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In DC circuits the charge carriers move uniformly through the entire cross sectional area of the wire. In AC circuits the current is constrained to travel in a thin "skin" just below the surface of the wire, effectively reducing the cross-sectional area of the wire. The effect becomes more pronounced the higher the frequency of the AC circuit.

Can anyone please give me a physical explanation of why the charge carriers are confined to the "skin" in an AC circuit. Or could you please direct me to a source where this is worked out explicitly?

Thank you!
 
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In a medium with finite conductivity the current slowly diffuses into the interior of the conductor from outside in. For a sinusoidal current the amplitude decays exponentially as you move into the conductor.
 
In a finite conductor, the ac currents generate azimuthal magnetic fields, which in turn generate eddy currents in the conductor. The eddy currents act to oppose the primary magnetic field, and force the ac currents to the outer edge of the conductor. the effective ac resistance of a cylindrical conductor is the equivalent to the resistivity of a conductor of area δ (the skin depth) times 2πR (the circumference).

The steady-state skin depth problem is solved exactly for cylindrical conductors in Smythe Static and Dynamic Electricity third edition, Section 10.02[STRIKE] using modified Bessel functions[/STRIKE].

Bob S
 
Last edited:
Thanks Bob S. That was very helpful. It surprises me that for such an interesting and seemingly common effect more textbooks don't discuss it. Jackson only talks about skin depth, but not the skin effect. Thanks again!
 
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