Essential University Physics - Alfredo Caguao · Slide 21-29 Summary • Gauss’s lawis one of the...

Copyright © 2007 Pearson Education, Inc., publishing as Pearson Addison-Wesley

PowerPoint® Lecture prepared by Richard Wolfson

Slide 21-1

21Gauss’s Law

Essential University PhysicsRichard Wolfson

2Copyright © 2007 Pearson Education, Inc., publishing as Pearson Addison-Wesley

In this lecture you’ll learn

• To represent electric fields using field-line diagrams

• To explain Gauss’s law and how it relates to Coulomb’s law

• To calculate the electric fields for symmetric charge distributions using Gauss’s law

• To describe the behavior of charge on conductors in electrostatic equilibrium


Electric field lines

• Electric field lines provide a convenient and insightful way to represent electric fields.

• A field line is a curve whose direction at each point is the direction of the electric field at that point.

• The spacing of field lines describes the magnitude of the field.

• Where lines are closer, the field is stronger.

Vector and field-line diagrams of a point-charge field

Tracing the field

of an electric dipole


Field lines for simple charge distributions

• There are field lines everywhere, so every charge distribution has infinitely many field lines.

• In drawing field-line diagrams, we associate a certain finite number of field lines with a charge of a given magnitude.

• In the diagrams shown, 8 lines are associated with a charge of magnitude q.

• Note that field lines of static charge distributions always begin and end on charges, or extend to infinity.


Counting field lines

• How many field lines emerge from closed surfaces surrounding charge?

• Count each field line crossing going outward as +1, each inward crossing as –1.

• You’ll find that the number of field lines crossing any closed surface is proportional to the net charge enclosed.


Electric flux

• Electric flux quantifies the notion “number of field lines crossing a surface.”

• The electric flux through a flat surface in a uniform electric field depends on the field strength E, the surface area A, and the angle between the field and the normal to the surface.

• Mathematically, the flux is given by

• Here is a vector whose magnitude is the surface area A and whose orientation is normal to the surface.

cos .EA E A

A


Electric flux with curved surfaces and

nonuniform fields

• When the surface is curved or the field is nonuniform, we calculate the flux by dividing the surface into small patches , so small that each patch is essentially flat and the field is essentially uniform over each.

• We then sum the fluxesover each patch.

• In the limit of infinitely manyinfinitesimally small patches,the sum becomes asurface integral:

dA

d E dA

E dA


Clicker question

• The flux through side B of the cube in the figure is the same as the flux through side C. What is a correct expression for the flux through each of these sides?

A.

B.

C.

D.

3s E

2s E

3 cos45s E

2 cos45s E


Gauss’s law

• Slide 5 showed that the number of field lines emerging from a closed surface is proportional to the net charge enclosed.

• In the language of electric flux, this statement becomesThe electric flux through any closed surface is proportional to the charge enclosed.

• The proportionality constant is 4pk, also called 1/0.

• Therefore

where the circle designates any closed surface, and the integral is taken over the surface. qenclosed is the charge enclosed by that surface.

• This statement is Gauss’s law.

• Gauss’s law is one of the four fundamentallaws of electromagnetism.

• It’s true for any surface and chargeanywhere in the universe.

• Gauss’s law is equivalent to Coulomb’s law;both describe the inverse square dependenceof the point-charge field.

enclosed

0

qE dA

O


Using Gauss’s law

• Gauss’s law is always true.

• But it’s useful for calculating the electric field only in situations with sufficient symmetry:

• Spherical symmetry

• Line symmetry

• Plane symmetry

Gauss’s law is always true, so it holds in both situations

shown. Both surfaces surround the same net charge, so the

flux through each is the same. But only the left-hand

situation has enough symmetry to allow the use of Gauss’s

law to calculate the field. The electric fields differ in the

two situations, even though the flux doesn’t.


Clicker question

• A spherical surface surrounds an isolated positive charge. We can calculate the electric flux for this surface. If a second charge is placed outside the spherical surface, what happens to the magnitude of the flux?

A. The flux increases proportionally to the magnitude of the second charge.

B. The flux decreases proportionally to the magnitude of the second charge.

C. The flux does not change.

D. The answer depends on whether the second charge is positive or negative.


Gauss’s law: A problem-solving strategy

• INTERPRET: Check that your charge distribution has sufficient symmetry.

• DEVELOP: Draw a diagram and use symmetry to find the direction of the electric field. Then draw a gaussian surface on which you’ll be able to evaluate the surface integral in Gauss’s law.

• EVALUATE:

• Evaluate the flux over your surface. The result contains the

unknown field strength E.

• Evaluate the enclosed charge.

• Equate the flux to qenclosed/0 and solve for E.

• ASSESS: Check that your answer makes sense, especially in comparison to charge distributions whose fields you know.

E dA

O


Example: The field of a uniformly charged

sphere

• INTERPRET: The situation has spherical symmetry.

• DEVELOP: Appropriate gaussian surfacesare spheres.

• EVALUATE:

• The flux becomes

• Outside the sphere, the enclosed charge isthe total charge Q.

• Then

• Thus the field outside a spherical charge distribution is identical to that of a point charge.

• Inside the sphere, the enclosed charge is proportional to the volume enclosed: qenclosed = (r3/R3)Q.

• Then 4πr2 E = (r3/R3)Q, so

24 .r EE dA p

2

0 2 2

0

4 , so .4

Q kQr E Q E

r rp

p

3

0

.4

QrE

Rp

O


A hollow spherical shell

• Applying Gauss’s law to a hollow spherical shell is similar to that for a spherical charge, but now the enclosed charge is zero.

• Therefore 4pr2E = 0, so the field inside the shell is zero.

• This can be understood in terms of Coulomb’s law because the inverse square dependence of the electric field results in cancellation at any point in the shell by the greater but more distant charge and the lesser but closer charge.


Clicker question

• A spherical shell carries charge Q uniformly distributed over its surface. If the charge on the shell doubles, what happens to the electric field strength inside the shell?

A. The electric field strength is zero.

B. The electric field strength quadruples.

C. The electric field strength is halved.

D. The electric field strength doubles.


Line symmetry

• In line symmetry, the charge density depends only on the perpendicular distance from a line, the axis of symmetry.

• This requires a charge distribution that is infinitely long.

• However, line symmetry is a good approximation for finite cylindrical charge distributions with length much greater than diameter, at points close to the charge.

• Applying Gauss’s law in line symmetry requires the use of a cylindrical gaussian surface.

• The flux through this gaussian surface is 2prLE.

• Applying Gauss’s law then shows that the field outside any charge distribution with line symmetry has the 1/r dependence of a line charge.

• The field inside a hollow charged cylinder is zero.


Plane symmetry

• In plane symmetry, the charge density depends only on the perpendicular distance from a plane, the plane of symmetry.

• This requires a charge distribution that extends infinitely in two directions.

• However, plane symmetry is a good approximation for finite slabs of charge whose thickness is much less than their extent in the other two dimensions, at points close to the charge.

• Applying Gauss’s law in plane symmetry requires the use of a gaussian surface that straddles the plane.

• The flux through this gaussian surface is 2AE.

• Applying Gauss’s law then shows that the field outside any charge distribution with plane symmetry is uniform and given by E = /20, where is the surface charge density.

• This makes sense because the symmetry precludes the field lines spreading in any particular direction.


Fields of arbitrary charge distributions

• Many real charge distributions can be approximated by the simple distributions considered in this chapter.

• In many cases one approximation applies close to the distribution, another far away.

• Far from any finite-size distribution, the field approaches that of a point charge.

• Far from any neutral distribution, the field generally approaches that of a dipole.

• Near a flat, uniformly charged region the field resembles the uniform field of a plane charge.


Clicker question

• A square sheet with charge Q uniformly distributed measures 1 m on each side? Which one of the following expressions would you use to approximate the electric field strength at a distance of 1 cm somewhere near the center of the sheet?

A.

C.

D.

E.

kQ

rE

2

kQ

rE

02 E

04 E


Gauss’s law and conductors

• Charges in conductors are free to move, and they do so in response to an applied electric field.

• If a conductor is allowed to reach electrostatic equilibrium, a condition in which there is no net charge motion, then charges redistribute themselves to cancel the applied field inside the conductor.

• Therefore the electric field is zero inside a conductor in electrostatic equilibrium.


Charged conductors

• Gauss’s law requires that any free charge on a conductor reside on the conductor surface.

• When charge resides inside a hollow, charged conductor, then there may be charge on the inside surface of the conductor. This charged conductor (shaded) carries a net charge of

1 C. There’s a 2- C point charge within a hollow

cavity in the conductor. Notice how the charge

redistributes itself to be consistent with Gauss’s law.


Clicker question

• A conductor carries a net charge of +Q. A cavity within the conductor contains a point charge of −Q. What is the charge on the outer surface of the conductor in electrostatic equilibrium?

A.

B.

C.

D.

Q

0

Q

2Q


The field at a conductor surface

• The electric field at the surface of a charged conductor in electrostatic equilibrium is perpendicular to the surface.

• If it weren’t, charge would move along the surface until equilibrium was reached.

• Gauss’s law shows that the field at the conductor surface has magnitude E = /0, where is the local surface charge density.


Summary

• Gauss’s law is one of the four fundamental laws of electromagnetism.

• In terms of the field line representation of electric fields, Gauss’s law expresses the fact that the number of field lines emerging from any closed surface is proportional to the net charge enclosed.

• Mathematically, Gauss’s law states that the electric flux

enclosed 0E dA q

E dA

O

O

through any closed surface is proportional to the net charge enclosed:

• Gauss’s law embodies the inverse-square dependence of the point-charge field, and is equivalent to Coulomb’s law.

• Gauss’s law is always true.

• It can be used to calculate electric fields in situations with sufficient symmetry:

spherical symmetry, line symmetry, or plane symmetry.

• Gauss’s law requires that any net charge on a charged conductor reside on the conductor surface, and that the electric field at the conductor surface be perpendicular to the surface.

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