ENE 325 Electromagnetic Fields and Waves

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Presentation transcript:

ENE 325 Electromagnetic Fields and Waves Lecture 5 Conductor, Semiconductor, Dielectric and Boundary Conditions 22/09/61

Review (1) The electric potential difference Vba is a work done by an external force to move a charge from point a to point b in an electric field divided by the amount of charge moved. The electric potential is the same no matter which routes are used. Only displacement distance (shortest route) matters 22/09/61

Review (2) Conductors and Ohm’s law Current, I is defined as the amount of charge that passes through a reference plane in a given amount of time. Ampere. Current density, J is defined as the amount of current per unit area A/m2 the relationship between I and J, convection current conduction current 22/09/61

Outline Conductor and boundary conditions Semiconductor and insulator 22/09/61

Conductors and boundary conditions charge density is zero inside a conductor Surface charge density DS is on the conductor surface An electric field inside a conductor is zero outside charges cause and electric field. 22/09/61

Tangential and normal fields. The electric field on the surface can be divided into two components. tangential electric field, Et, = 0 for an equipotential surface normal electric field, En 22/09/61

Boundary conditions (1) Consider a conductor-free space boundary From 22/09/61

Boundary conditions (3) Consider Gauss’s law From 22/09/61

Boundary conditions (3) For conductor-free space boundary conditions (B.Cs.) Dt = Et = 0 Dn = 0En = s 22/09/61

Ex1 Let V and let a point P(0 Ex1 Let V and let a point P(0.1, /12, /24) locate at the conductor-free space boundary. At point P, determine V E 22/09/61

c) En d) Et e) S 22/09/61

Semiconductors Electron and hole currents conductivity mobility is 10-100 times higher than conductor. electron and hole density depend on temperature. Doping is the process of adding impurities to a semiconductor to alter the polarity. 22/09/61

Dielectric or insulator no free charge microscopic electric dipoles energy stored capability polar and non-polar molecules polar molecules non-polar molecules 22/09/61

Alignment of dipoles with E field 22/09/61

Polarization Each dipole has its dipole moment, where Q is the positive one of the two bound charges is the vector from the negative to the positive charge. where n = number of dipoles per volume. Polarization is dipole moment per unit volume, 22/09/61

Equivalent polarization The movement of bound charges when induced by an electric field causes changes in surface and volume charge densities. Equivalent polarization surface charge density, s Equivalent polarization volume charge density, v 22/09/61

Electric flux density in a dielectric material (1) can be calculated from free and bound charges. Net bound charges flowing out of the closed surfaces, Let where QT = total charge Q = free charge 22/09/61

Electric flux density in a dielectric material (2) From then Let we can write where is an electric flux density in a dielectric material. 22/09/61

Equivalent divergence relationships From use a divergence theorem, we have Since then We can also show that therefore 22/09/61

Electric flux density in dielectric medium (1) If the dielectric material is linear and isotropic, the polarization is proportional to the electric field . where e is an electric susceptibility. Then Let where r is a relative permittivity or a dielectric constant 22/09/61

Electric flux density in dielectric medium (2) So we can write or where F/m. . 22/09/61

Ex2 A dielectric material has an electric susceptibility e =0 Ex2 A dielectric material has an electric susceptibility e =0.12 and has a uniform electric flux density D = 1.6 nC/m2, determine a) E b) P c) Average dipole moment if there are 2x1019 dipoles/m3 . 22/09/61

Boundary conditions for dielectric materials: tangential fields It is useful to determine the electric field in a dielectric medium. Dielectric-Dielectric Et1 =Et2 and 22/09/61

Boundary conditions for dielectric materials: normal fields Dielectric-Dielectric For a free of charge boundary, Dn1 = Dn2 and 1En1 = 2En2. is the unit vector pointing from medium 2 to medium 1 22/09/61

Use B.C.s to determine magnitude of and 22/09/61

Ex3 The isotropic dielectric medium with r1 = 3 and r2 = 2 is connected as shown. Given V/m, determine and its magnitude, and its magnitude, 1, and 2. 22/09/61

Boundary conditions for dielectric-conductor Dt = Et = 0 Dn = En = s 22/09/61

Ex4 Between a dielectric-conductor interface has a surface charge density of s = 2x10-9 C/m2. Given V/m, determine . 22/09/61