chapter 21 electric charge and electric fields

Chapter 21 Electric Charge and Electric Fields

• What is a field? • Why have them?• What causes fields?

Field Type Caused Bygravity masselectric charge

magnetic moving charge

Electric Charge• Types:

– Positive• Glass rubbed with silk • Missing electrons

– Negative• Rubber/Plastic rubbed with fur• Extra electrons

• Arbitrary choice – convention attributed to ?

• Units: amount of charge is measured in [Coulombs]

• Empirical Observations:– Like charges repel– Unlike charges attract

Charge in the Atom

• Protons (+)• Electrons (-)• Ions• Polar Molecules

Charge Properties• Conservation

– Charge is not created or destroyed, only transferred.– The net amount of electric charge produced in any

process is zero.

• Quantization– The smallest unit of charge is that on an electron or

proton. (e = 1.6 x 10-19 C)• It is impossible to have less charge than this• It is possible to have integer multiples of this charge

Q Ne

Conductors and Insulators• Conductor transfers charge on contact• Insulator does not transfer charge on contact• Semiconductor might transfer charge on contact

Charge Transfer Processes• Conduction• Polarization• Induction

The Electroscope

Coulomb’s Law• Empirical Observations

• Formal Statement

1 2F q q

2

1Fr

Direction of the force is along the line joining the two charges

1 212 122

12

kq q ˆF rr

Active Figure 23.7

(SLIDESHOW MODE ONLY)

Coulomb’s Law Example

• What is the magnitude of the electric force of attraction between an iron nucleus (q=+26e) and its innermost electron if the distance between them is 1.5 x 10-12 m

Hydrogen Atom Example

• The electrical force between the electron and proton is found from Coulomb’s law– Fe = keq1q2 / r2 = 8.2 x 108 N

• This can be compared to the gravitational force between the electron and the proton– Fg = Gmemp / r2 = 3.6 x 10-47 N

Subscript Convention

1 212 122

12

kq q ˆF rr

12 2 1F force on charge q due to charge q

12 1 1r distance from charge q to charge q

12 1 2r̂ unit vector oriented from charge q to charge q

+q1 +q2

12r̂ 12F

12r

More Coulomb’s Law

Coulomb’s constant:2 2

9 92 2

o

N m N m 1k 8.988x10 9.0x10C C 4

permittivity of free space:2

12o 2

1 C8.85x104 k N m

1 212 122

12

kq q ˆF rr

1212

12

rr̂r

Charge polarity: Same sign Force is rightOpposite sign Force is Left

Electrostatics --- Charges must be at rest!

+q1 +q2

12r̂ 12F

12r

12r

Superposition of Forces

0 10 20 30F F F F ....

0 1 0 2 0 30 10 20 302 2 2

10 20 30

kq q kq q kq qˆ ˆ ˆF r r r ....r r r

N31 2 i

0 0 10 20 30 0 i02 2 2 2i 110 20 30 i0

qq q qˆ ˆ ˆ ˆF kq r r r .... kq rr r r r

+Q3

+Q2

+Q1

+Q0

10F

30F

20F

10r

20r

30r

Coulomb’s Law Example

• Q = 6.0 mC• L = 0.10 m• What is the magnitude

and direction of the net force on one of the charges?

F1

+

F2

F3

Q

x

y

L

++

+

L

QQ

Q

Zero Resultant Force, Example

• Where is the resultant force equal to zero?– The magnitudes of the

individual forces will be equal

– Directions will be opposite

• Will result in a quadratic• Choose the root that

gives the forces in opposite directions

q1 = 15.0 Cq2 = 6.0 C

Electrical Force with Other Forces, Example

• The spheres are in equilibrium

• Since they are separated, they exert a repulsive force on each other– Charges are like charges

• Proceed as usual with equilibrium problems, noting one force is an electrical force

Electrical Force with Other Forces, Example cont.

• The free body diagram includes the components of the tension, the electrical force, and the weight

• Solve for |q| • You cannot

determine the sign of q, only that they both have same sign

The Electric Field• Charge particles create forces on each other without ever

coming into contact. » “action at a distance”

• A charge creates in space the ability to exert a force on a second very small charge. This ability exists even if the second charge is not present.

• We call this ability to exert a force at a distance a “field”• In general, a field is defined:

• The Electric Field is then: test quantity 0

ForceField limtest quantity

q 0

FE limq

NC

Why in the limit?

Electric Field near a Point Charge

oq 0o

FE limq

o2

kq q ˆF rr

o

o2

2q 0o

kqq r̂ kqr ˆE lim rq r

+Q -Q

Electric Field Vectors

Electric Field Lines

Active Figure 23.13

(SLIDESHOW MODE ONLY)

Rules for Drawing Field Lines• The electric field, , is tangent to the field lines.• The number of lines leaving/entering a charge is

proportional to the charge.• The number of lines passing through a unit area normal to

the lines is proportional to the strength of the field in that region.

• Field lines must begin on positive charges (or from infinity) and end on negative charges (or at infinity). The test charge is positive by convention.

• No two field lines can cross.

E

# of electric field linesEArea

Electric Field Lines, General

• The density of lines through surface A is greater than through surface B

• The magnitude of the electric field is greater on surface A than B

• The lines at different locations point in different directions– This indicates the field is

non-uniform

Example Field Lines

+ + + + +

Dipole Line Charge

Q dqdx

Linear Charge Density:

For a continuous linear charge distribution,

Active Figure 23.24

(SLIDESHOW MODE ONLY)

More Field Lines

Q dqA dA

Surface Charge Density:

Q dqV dV

Volume Charge Density:

Superposition of Fields

P 1P 2P 3PE E E E ....

31 2P 10 20 302 2 2

10 20 30

kqkq kqˆ ˆ ˆE r r r ....r r r

N31 2 i

P 10 20 30 i02 2 2 2i 110 20 30 i0

qq q qˆ ˆ ˆ ˆE k r r r .... k rr r r r

+q3

+q2

+q1

10E

30E

20E

10r

20r

30rP

Superposition Example

• Find the electric field due to q1, E1

• Find the electric field due to q2, E2

• E = E1 + E2– Remember, the fields add

as vectors– The direction of the

individual fields is the direction of the force on a positive test charge

Electric Field of a Dipole

p2a

-q +q

E

yE

E E E

22

kqE Ey a

x xE E E 2E cos

32 2 2 22 2 2

kq a kpE 2y a y a y a

y 2a3

kpEy

p 2aq

ExampleThree point charges are

arranged as shown in Figure P23.19.

(a) Find the vector electric field that the 6.00-nC and –3.00-nC charges together create at the origin.

(b) (b) Find the vector force on the 5.00-nC charge.

Figure P23.19

ExampleThree point charges are

aligned along the x axis as shown in Figure P23.52. Find the electric field at

(a) the position (2.00, 0) and

(b) the position (0, 2.00).Figure P23.52

9 2 2 9

1 2 2

8.99 10 N m C 4.00 10 C ˆˆ2.50 m

ˆ5.75 N C

ek qr

E r i

i

9 2 2 9

2 2 2

8.99 10 N m C 5.00 10 C ˆ ˆˆ 11.2 N C 2.00 m

ek qr

E r i i

9 2 2 9

3 2

8.99 10 N m C 3.00 10 C ˆ ˆ18.7 N C 1.20 m

E i i

1 2 3 24.2 N CR E E E E

FIG. P23.52(a)

in +x direction.

1 2ˆ ˆˆ 8.46 N C 0.243 0.970ek q

r E r i j

2 2

3 2

1 3 1 2 3

ˆˆ 11.2 N C

ˆ ˆˆ 5.81 N C 0.371 +0.928

ˆ ˆ4.21 N C 8.43 N C

e

e

x x x y y y y

k qrk qr

E E E E E E E

E r j

E r i j

i j

9.42 N CRE 63.4 above axisx

P23.19

9 91 3

1 2 21

8.99 10 3.00 10ˆ ˆ ˆ2.70 10 N C0.100

ek qr

E j j j

9 92 2

2 2 22

2 32 1

8.99 10 6.00 10ˆ ˆ ˆ5.99 10 N C0.300

ˆ ˆ5.99 10 N C 2.70 10 N C

ek qr

E i i i

E E E i j

9 ˆ ˆ5.00 10 C 599 2700 N Cq F E i j

6 6ˆ ˆ ˆ ˆ3.00 10 13.5 10 N 3.00 13.5 N F i j i j

(a)

(b)

Motion of Charged Particles in a Uniform Electric Field

-e

-Q +Q

q 0

FE limq

F qE ma

qEam

2 20 0v v 2a x x

x x

e Ev 2a x 2 x

m

x

Example

• A proton accelerates from rest in a uniform electric field of 500 N/C. At some time later, its speed is 2.50 x 106 m/s.– Find the acceleration of the

proton.– How long does it take for the

proton to reach this speed?– How far has it moved in this time?– What is the kinetic energy?

e

-Q +Q

x

Motion of Charged Particles in a Uniform Electric Field

-e

+Q

-Q

q 0

FE limq

F qE ma

y

e Ea

m

x x0 x x0v v a t v

y y0 y

e Ev v a t t

m

x0v

2

2 2 2x y x0

e E tv v v v

m

v

1

x0

e E ttan

mv

Active Figure 23.26

(SLIDESHOW MODE ONLY)

Motion of Charged Particles in a Uniform Electric Field

-e-e

-Q +Q

+Q

-Qx

Phosphor Screen

This device is known as a cathode ray tube (CRT)

DipolesThe combination of two equal charges of opposite sign, +q and –q, separated by a distance l

p q2a qL p

2a L

-q +q

1p

2p

1 2p p p

p qL

Dipoles in a Uniform Electric Field

p2a L

-q

+q F qE

F qE

E

F a sin F a sin qEa sin qEa sin q2aEsin pEsin

x y z

ˆ ˆ ˆi j kr F x y z

F F F

r F sin

p E

Work Rotating a Dipole in an Uniform Electric Field

p2a L

-q

+q F qE

F qE

E

fielddW d pE sin d dU

oLet: U( =90 ) 0 U pE cos

U p E

0U pE sin d pE cos U

0U 0