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Christopher Crawford PHY

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Presentation on theme: "Christopher Crawford PHY"— Presentation transcript:

1 Christopher Crawford PHY 311 2014-03-07
§4.2–3 Displacement Christopher Crawford PHY 311

2 Outline Review – D=ε0E+P New Gauss’ law – displacement field boundary conditions – obtained as usual Constitutive equation – ε = ε0εr = ε0(1+χe) Electric susceptibility – P vs E, compare: polarizability Dielectric constant – amplification of free charge [relative] permittivity – D vs E Examples parallel plate capacitor polarized sphere dielectric sphere in an external field

3 New Gauss’ (flux) law: Old (flow) law: MACROSCOPIC formulation
New field: D = ε0E + P (electric displacement) Derived from E, P Gauss’ laws Corresponding boundary condition Old (flow) law: E field still responsible for force -> potential energy V is still defined in terms of E Boundary conditions: potential still continuous

4 Polarizability vs. Susceptibility
Dipole moment of single atom in an electric field Susceptibility Polarization [density] of a material in an electric field Relation between the two Clausius-Mossotti relationship

5 Dielectric material properties
In general the polarization is an arbitrary function of: Electric field, position(wavelength), time(frequency), temperature, … “Electrets” even have polarization independent of E However most materials satisfy the following properties which makes it much easier to calculate the fields: Linear – χe independent of magnitude of E Polarization proportional to electric field Isotropic – χe independent of direction of E Polarization in the same direction as electric field Homogeneous – χe independent of position Material doesn’t change from place to place

6 Permittivity: constitutive equation
Link between D and E in Maxwell’s equations Susceptibility Relative permittivity (dielectric constant) Permittivity of free space [vacuum] Absolute permittivity Relations between constants Permittivity reflects the same material properties as susceptibility: linear, isotropic, homogeneous In general it is a tensor (matrix) function ε(E,r,ω,…)

7 Macroscopic potential formulation
Poisson’s equation  Laplace’s equation Continuity boundary conditions

8 Example: Parallel plates w/dielectric

9 Example: Polarized dielectric

10 Example: dielectric sphere in external E

11 Example: dielectric sphere in external E

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