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Gauss’s Law
The beauty of 1/R2
“From our derivation you see that Gauss' law follows from the fact that the exponent in Coulomb's law is exactly two. A 1/r3 field, or any 1/rn field with n ≠ 2, would not give Gauss' law. So Gauss' law is just an expression, in a different form, of the Coulomb law...”
-- Richard Feynman
RE ˆ4 2
0R
q
0
22
0
20
41
4
ˆ1
4
q
RR
q
dR
qd
sRsE
For a point charge,
a constant for any R.
For a chunk of charge,
00 Q
dVd sE
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Another look at the parallel-plate capacitor (Two infinitely large sheets of opposite charges)
Gauss’s law leads to
Here, the negative sign just signifies the “downward” direction.It’s kind of arbitrary.
Electric Fields in Insulators (Dielectrics)
Polarization1. Electronic polarization
d
p = qd
2. Ionic polarization
3. Orientational polarization
Dipole
pointing from to +
When E = 0, p = 0.
Vi
i
V
pP
0lim
Define polarization
When E = 0, net dipole is 0, therefore P = 0. A finite E will induce a net polarization P.
Again, P = 0 (no net dipole) when E = 0. A finite E induces a net polarization P by line up the dipoles.
In all cases, no matter what the mechanism is, E induces P.For materials without spontaneous polarization and for not too strong E, P E.
P = 0E
Not net charge
No net charge in the interior.Two sheet charges at surfaces.
d
(sPA)d = P(Ad)
sP = P
The polarization charge, or “internal” charge, density
The polarization (or “internal”) charge leads to a polarization (or “internal”) field
0EP = P
EP = sP/0
EP = P/0
(external, applied)
EP
Notice that the polarization (internal) filed is always in opposite direction to the external, applied field Eext.
0EP = P
Eext
(total field)
(external, applied)
EP
Now consider a parallel capacitor filled with this dielectric between the two plates.External surface charge density s
induces external field
Eext = s/0
The polarization (or internal) field
EP = sP/0 = P/0
The total field
E = Eext + EP
E = Eext EP = s/0 P/0 Recall thatP = 0EE = s/0 E
Notice this is the total field
(1+)E = s/0
Define r = 1+, and we have: rE = s/0
r0E = s
Define = 0r = 0(1+), and we have: E = s
We often write as e, thus re 00 )1(
We lump the polarization effect of a dielectric material into a parameter ,and substitute 0 (for free space) with (for the dielectric) in equations.
(total field)Eext
Not net charge
d
On both surfaces of a dielectric slabsP = P (ignoring sign)
Recall that the field of a parallel-plate capacitor is the consequenceof Gauss’s law applied to the surface charge densities:
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PP sP = P
Notice the sign
By analogy:
Generalize to other geometries:
EP 0e
PP
PE0
DE)( 00 e ,
where re 00 )1( ,
EED r0
E 0
total0
)(11
P
E P00
1
Gauss’s law in dielectrics
We lump the polarization effect of a dielectric material into a parameter ,and substitute 0 (for free space) with (for the dielectric) in equations.
Gauss’s law in dielectrics
Take-home message:
Limitations of our discussion:• No spontaneous polarization (or piezoelectric effect): whenever
E = 0, P = 0 • Linearity: P = 0E, D = E• Isotropy: The proportional constants are the same in all
directions, thus P // E, D // E