03_chapter_23 gauss law principle and definition.ppt
silidjr
0 views
22 slides
Oct 15, 2025
Slide 1 of 22
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
About This Presentation
03_chapter_23 gauss law principle and definition.ppt
Slide Content
Chapter 23. Gauss’ Law
23.1. What is Physics?
23.2. Flux
23.3. Flux of an Electric Field
23.4. Gauss' Law
23.5. Gauss' Law and Coulomb's Law
23.6. A Charged Isolated Conductor
23.7. Applying Gauss' Law: Cylindrical Symmetry
23.8. Applying Gauss' Law: Planar Symmetry
23.9. Applying Gauss' Law: Spherical Symmetry
23.1. What is Physics?
23.2. Flux
23.3. Flux of an Electric Field
23.4. Gauss' Law
23.5. Gauss' Law and Coulomb's Law
23.6. A Charged Isolated Conductor
23.7. Applying Gauss' Law: Cylindrical Symmetry
23.8. Applying Gauss' Law: Planar Symmetry
23.9. Applying Gauss' Law: Spherical Symmetry
What is Physics?
•Gaussian surface is a hypothetical
(any imaginary shape) closed
surface enclosing the charge
distribution.
•Gauss' law relates the electric
fields at points on a (closed)
Gaussian surface to the net
charge enclosed by that surface.
•Gaussian surface is a hypothetical
(any imaginary shape) closed
surface enclosing the charge
distribution.
•Gauss' law relates the electric
fields at points on a (closed)
Gaussian surface to the net
charge enclosed by that surface.
Gaussian surface
Let us divide the surface into
small squares of area ΔA, each
square being small enough to
permit us to neglect any
curvature and to consider the
individual square to be flat. We
represent each such element
of area with an area vector
•Magnitude is the area ΔA.
•Direstion is perpendicular to
the Gaussian surface and
directed away from the
interior of the surface.
Let us divide the surface into
small squares of area ΔA, each
square being small enough to
permit us to neglect any
curvature and to consider the
individual square to be flat. We
represent each such element
of area with an area vector
•Magnitude is the area ΔA.
•Direstion is perpendicular to
the Gaussian surface and
directed away from the
interior of the surface.
Flux
The rate of volume flow through the loop is :
The rate of volume flow through the loop is :
Flux of an Electric Field
•The electric field for a surface is
The electric flux Φ through a
Gaussian surface is proportional to
the net number of electric field lines
passing through that surface.
•The electric field for a gaussian
surface is
SI Unit of Electric Flux: N·m
2
/C
•The electric field for a surface is
The electric flux Φ through a
Gaussian surface is proportional to
the net number of electric field lines
passing through that surface.
•The electric field for a gaussian
surface is
SI Unit of Electric Flux: N·m
2
/C
Problem 1
The drawing shows an edge-on view of two
planar surfaces that intersect and are
mutually perpendicular. Surface 1 has an area
of 1.7 m
2
, while surface 2 has an area of 3.2
m
2
. The electric field E in the drawing is
uniform and has a magnitude of 250 N/C. Find
the electric flux through (a) surface 1 and (b)
surface 2.
The drawing shows an edge-on view of two
planar surfaces that intersect and are
mutually perpendicular. Surface 1 has an area
of 1.7 m
2
, while surface 2 has an area of 3.2
m
2
. The electric field E in the drawing is
uniform and has a magnitude of 250 N/C. Find
the electric flux through (a) surface 1 and (b)
surface 2.
Sample Problem 2
Figure 23-4 shows a Gaussian surface in the form of
a cylinder of radius R immersed in a uniform electric
field E , with the cylinder axis parallel to the field.
What is the flux Φ of the electric field through this
closed surface?
Figure 23-4 shows a Gaussian surface in the form of
a cylinder of radius R immersed in a uniform electric
field E , with the cylinder axis parallel to the field.
What is the flux Φ of the electric field through this
closed surface?
Sample Problem 3
A nonuniform electric field given by
pierces the Gaussian cube shown in Fig. (E is in
newtons per coulomb and x is in meters.) What is the
electric flux through the right face, the left face,
the top face, and the Gaussian surface?
A nonuniform electric field given by
pierces the Gaussian cube shown in Fig. (E is in
newtons per coulomb and x is in meters.) What is the
electric flux through the right face, the left face,
the top face, and the Gaussian surface?
Gauss’ Law
For a point charge:
2
0
1
,
4
q
E k k
r
2 2
0 0 0
1
4 (4 )
q q q
E
r r A
For a point charge:
2
0
1
,
4
q
E k k
r
2 2
0 0 0
1
4 (4 )
q q q
E
r r A
Gauss’ Law
For charge distribution Q:
The electric flux through a Gaussian surface
times by ε
0 ( the permittivity of free space)
is equal to the net charge Q enclosed :
•The net charge q
enc
is the algebraic sum
of all the enclosed charges.
•Charge outside the surface, no matter how
large or how close it may be, is not included
in the term q
enc
.
For charge distribution Q:
The electric flux through a Gaussian surface
times by ε
0 ( the permittivity of free space)
is equal to the net charge Q enclosed :
•The net charge q
enc
is the algebraic sum
of all the enclosed charges.
•Charge outside the surface, no matter how
large or how close it may be, is not included
in the term q
enc
.
Check Your Understanding
The drawing shows an arrangement of three charges. In
parts (a) and (b) different Gaussian surfaces are
shown. Through which surface, if either, does the
greater electric flux pass?
The drawing shows an arrangement of three charges. In
parts (a) and (b) different Gaussian surfaces are
shown. Through which surface, if either, does the
greater electric flux pass?
Sample Problem
Figure 23-7 shows five charged lumps of plastic and an
electrically neutral coin. The cross section of a
Gaussian surface S is indicated. What is the net
electric flux through the surface if q
1
=q
4
=3.1 nC,
q
2=q
5=-5.9 nC, and q
3=-3.1 nC?
Figure 23-7 shows five charged lumps of plastic and an
electrically neutral coin. The cross section of a
Gaussian surface S is indicated. What is the net
electric flux through the surface if q
1
=q
4
=3.1 nC,
q
2=q
5=-5.9 nC, and q
3=-3.1 nC?
A Charged Isolated Conductor
•If an excess charge is placed on an
isolated conductor, that amount of
charge will move entirely to the surface
of the conductor. None of the excess
charge will be found within the body of
the conductor.
•For an Isolated Conductor with a Cavity,
There is no net charge on the cavity
walls; all the excess charge remains on
the outer surface of the conductor
•If an excess charge is placed on an
isolated conductor, that amount of
charge will move entirely to the surface
of the conductor. None of the excess
charge will be found within the body of
the conductor.
•For an Isolated Conductor with a Cavity,
There is no net charge on the cavity
walls; all the excess charge remains on
the outer surface of the conductor
The External Electric Field of a Conductor
according to Gauss' law,
If σ is the charge per unit area,
according to Gauss' law,
If σ is the charge per unit area,
Sample Problem
Figure 23-11a shows a cross section of a spherical
metal shell of inner radius R. A point charge of q is
located at a distance R/2 from the center of the
shell. If the shell is electrically neutral, what are the
(induced) charges on its inner and outer surfaces?
Are those charges uniformly distributed? What is
the field pattern inside and outside the shell?
Figure 23-11a shows a cross section of a spherical
metal shell of inner radius R. A point charge of q is
located at a distance R/2 from the center of the
shell. If the shell is electrically neutral, what are the
(induced) charges on its inner and outer surfaces?
Are those charges uniformly distributed? What is
the field pattern inside and outside the shell?
Applying Gauss' Law: Cylindrical
Symmetry
Figure 23-12 shows a section of
an infinitely long cylindrical
plastic rod with a uniform
positive linear charge density λ.
Symmetry
Figure 23-12 shows a section of
an infinitely long cylindrical
plastic rod with a uniform
positive linear charge density λ.
Applying Gauss' Law: Planar Symmetry
Figure 23-15 shows a portion of a thin,
infinite, nonconducting sheet with a
uniform (positive) surface charge density
σ
Figure 23-15 shows a portion of a thin,
infinite, nonconducting sheet with a
uniform (positive) surface charge density
σ
Applying Gauss' Law: Spherical Symmetry
•A shell of uniform charge attracts
or repels a charged particle that is
outside the shell as if all the shell's
charge were concentrated at the
center of the shell.
•If a charged particle is located
inside a shell of uniform charge,
there is no electrostatic force on
the particle from the shell.
•A shell of uniform charge attracts
or repels a charged particle that is
outside the shell as if all the shell's
charge were concentrated at the
center of the shell.
•If a charged particle is located
inside a shell of uniform charge,
there is no electrostatic force on
the particle from the shell.
Any spherically symmetric charge distribution with
the volume charge density ρ
•For r>R, the charge produces an
electric field on the Gaussian
surface as if the charge were a
point charge located at the center,
•For r<R, the electric field is
the volume charge density ρ
•For r>R, the charge produces an
electric field on the Gaussian
surface as if the charge were a
point charge located at the center,
•For r<R, the electric field is
Checkpoint
The figure shows two large, parallel, nonconducting
sheets with identical (positive) uniform surface charge
densities, and a sphere with a uniform (positive) volume
charge density. Rank the four numbered points
according to the magnitude of the net electric field
there, greatest first.
The figure shows two large, parallel, nonconducting
sheets with identical (positive) uniform surface charge
densities, and a sphere with a uniform (positive) volume
charge density. Rank the four numbered points
according to the magnitude of the net electric field
there, greatest first.
Conceptual Questions
(1)Two charges, +q and –q, are inside a Gaussian surface. Since the
net charge inside the Gaussian surface is zero, Gauss’ law states
that the electric flux through the surface is also zero; that is
Φ=0. Does the fact that Φ =0 imply that the electric field E at
any point on the Gaussian surface is also zero? Justify your
answer.
(2)The drawing shows three charges, labeled q
1
, q
2
, and q
3
. A
Gaussian surface is drawn around q
1 and q
2. (a) Which charges
determine the electric flux through the Gaussian surface? (b)
Which charges produce the electric field at the point P? Justify
your answers.
(1)Two charges, +q and –q, are inside a Gaussian surface. Since the
net charge inside the Gaussian surface is zero, Gauss’ law states
that the electric flux through the surface is also zero; that is
Φ=0. Does the fact that Φ =0 imply that the electric field E at
any point on the Gaussian surface is also zero? Justify your
answer.
(2)The drawing shows three charges, labeled q
1
, q
2
, and q
3
. A
Gaussian surface is drawn around q
1 and q
2. (a) Which charges
determine the electric flux through the Gaussian surface? (b)
Which charges produce the electric field at the point P? Justify
your answers.
(3) A charge +q is placed inside a spherical Gaussian
surface. The charge is not located at the center of
the sphere. (a) Can Gauss’ law tell us exactly where
the charge is located inside the sphere? Justify your
answer. (b) Can Gauss’ law tell us about the magnitude
of the electric flux through the Gaussian surface?
Why?
surface. The charge is not located at the center of
the sphere. (a) Can Gauss’ law tell us exactly where
the charge is located inside the sphere? Justify your
answer. (b) Can Gauss’ law tell us about the magnitude
of the electric flux through the Gaussian surface?
Why?
Tags
Categories
EducationDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 0
- Slides 22
- Age 56 days
Related Slideshows
11
TLE-9-Prepare-Salad-and-Dressing.pptxkkk
MaAngelicaCanceran
40 views
12
LESSON 1 ABOUT MEDIA AND INFORMATION.pptx
JojitGueta
32 views
60
GRADE-8-AQUACULTURE-WEEKQ1.pdfdfawgwyrsewru
MaAngelicaCanceran
55 views
26
Feelings PP Game FOR CHILDREN IN ELEMENTARY SCHOOL.pptx
KaistaGlow
50 views
![Jeopardy_Figures_of_Speech_Template.pptx [Autosaved].pptx](https://slidepub.com/thumb/5828/284015828.jpg)
54
Jeopardy_Figures_of_Speech_Template.pptx [Autosaved].pptx
acecamero20
30 views
7
Jeopardy_Figures_of_Speech.pptxvdsvdsvsdvsd
acecamero20
31 views