A simple formula for the concentration of charge on a three-dimensional corner of a conductor

• Published in: IEEE transactions on microwave theory and techniques Vol. 44; no. 6; pp. 975 - 979
• Main Authors: Yimin Zhang, Zemanian, A.H.
• Format: Journal Article
• Language: English
• Published: IEEE 01.06.1996
• Subjects: Capacitance; Conductors; Electric potential; Finite difference methods; Microstrip; Microwave theory and techniques; Millimeter wave technology; Surface resistance; Time domain analysis; Very large scale integration
• ISSN: 0018-9480; 1557-9670
• DOI: 10.1109/22.506640

A major problem in the computation of capacitance coefficients for microwave transmission and VLSI interconnection systems is caused by the singularities in the electric field at the corners and edges of conductors. For edges, a solution is given by the Duncan correction, which is based on a two-dimensional (2-D) polar expansion of the field. No such exact expansion exists for corners. Recent research by Beagles and Whiteman (1989) has yielded an asymptotic expansion for the electric field in the vicinity of a rectangular three-dimensional conductive corner, and this is used to derive a simple formula for the charge Q (in coulombs) concentrated at any such corner. The formula is Q=1.307 /spl epsi/d(V/sub c/-V/sub s/), where /spl epsi/ is the dielectric permittivity (in farads per meter) of the medium surrounding the conductive corner, d is the length (in meters) of one side of a cubic region situated on the conductor adjacent to the corner, V/sub c/ is the electric potential (in volts) of the conductor, and V/sub s/ is the electric potential at a point in the medium displaced from the corner's apex along a line through the cube's diagonal and at a distance equal to that diagonal. Q is the charge on the cube's three surfaces lying along the conductor's surfaces. Such a configuration is convenient for a finite-difference computation of capacitance.