Electric field enhancement near a surface bump

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SUMMARY

The discussion focuses on calculating electric field enhancement near a hemispherical bump on a parallel plate capacitor. The average electric field at the tip of the bump is determined by the formula V/(h-r), where V is the voltage and h is the distance between the plates. To find the electric field away from the tip, one must identify the path of least distance (s) between the bump and the flat plate, ensuring that the electric field remains perpendicular to the surfaces. The solution involves using orthogonal special functions and matching boundary conditions for dielectric displacements, as referenced in a relevant academic paper.

PREREQUISITES
  • Understanding of electric fields and potential difference in capacitors
  • Familiarity with calculus of variations
  • Knowledge of boundary conditions in electrostatics
  • Experience with orthogonal special functions
NEXT STEPS
  • Study the application of calculus of variations in electrostatics
  • Research dielectric displacement and its boundary conditions
  • Learn about orthogonal special functions and their applications in physics
  • Review the referenced paper on electric field enhancement for deeper insights
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Physicists, electrical engineers, and students studying electromagnetism, particularly those interested in electric field behavior near geometrical discontinuities in capacitors.

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Homework Statement



Well I got a question regarding the electric field. So let's say an electric field E exists between two parallel plates. There is a hemispherical bump on one of the plates with radius of r, so how to calculate the electric field enhancement?

Thanks guys.
 
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If h is the distance between plates, then far away from the hump, V = Eh. At the tip of the hump, the average electric field has to be V/(h-r).

Away from the tip, you have to determine the path of least distance s between the spot on the hump and the flat plate. The boundary conditions are that the E field must be perpendicular to the hump surface at the hump surface, and to and at the bottom plate. This could be a problem in the calculus of variations. Once you have determined this distance the average E field is again V/s.
 

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