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Transcript
Gauss’s law
This lecture was given mostly on the board so these
slides are only a guide to what was done.
Gauss’s law
We have shown that the
number of field lines
emerging from a closed
surface is proportional to
the net charge enclosed
or
The electric flux through
any closed surface is
proportional to the charge
enclosed
Gauss’s law
follows from the
inverse square
aspect of
Coulomb’s law
TRUE or FALSE?
A
F
All particles contribute to the electric field at
point P on the surface.
The net flux of electric field through the surface
due to q3 and q4 is zero.
All True
The net flux of electric field through the surface
due to q1 and q2 is proportional to (q1 + q2).
 E d A 
qenc
0
Gauss’ Law
Gauss’s Law
Gauss’ Law relates the net flux  of an
electric field through a closed surface
to the net charge qenc that is enclosed
by that surface

 E d A 
qenc
0
qenc
0
- in vacuum (or air)
Gauss’ Law
• Charge outside not included
• Exact location of charges inside
doesn’t matter, only magnitude and
sign
• But, E is the resultant of all charges,
both inside and outside
Q
The net number
of electric field
lines out of each
surface is the
same
SHAPE OF
SURFACE
DOESN’T
MATTER

 E d A
Flux through the surface due to ALL
the charges
this charge contributes ZERO FLUX as
every field line from it that enters the
surface at one point, leaves at another
Example 21.1 Field of a uniformly
charged sphere
Total charge Q
Radius R
Done on board in lecture
Example 21.2
Field of a hollow spherical sphere
From Gauss’s law, E = 0 inside shell
Read Example 21.3
Field of a point charge within a shell
and TIP: SYMMETRY MATTERS!
Line symmetry
(Next lecture)
Example 21.4 Field of a line of charge
A section of an infinitely long
wire with a uniform linear
charge density, .
Find an expression for E at
distance r from axis of wire.

E
20 r
(line of charge)
Applying Gauss’ Law: cylindrical symmetry

E
20 r
(line of charge)
(Compare this result with that
obtained using Coulomb’s law in
Example 20.7, when wire is
infinitely long.)
Applies outside any
cylindrical charge
distribution