Electric Charge and Electric Field

AP Physics

Chapter 16

Electric Charge and Electric Field

16.1 Static Electricity

16.1 Static Electricity

Static electricity – not moving

Two types of charge

positive (+) when electrons are lost

negative (-) when electrons are gained

Objects can gain charges by rubbing

16.1

16.1 Static Electricity

Like charges repel

Unlike charges attract

Law of Conservation of electric charge – the net amount of electric charge produced in a process is zero

16.1

Electric Charge and Electric Field

16.2 Electric Charge in the Atom

16.2 Electric Charge in the Atom

Atoms are made of

positive protons

negative electrons

Electrons move from

one object to another when the objects

are rubbed

Eventually charges bleed off

objects because water

molecules are polar 16.2

Electric Charge and Electric Field

16.3 Insulators and Conductors

16.3 Insulators and Conductors

Conductors – outer

electrons of atoms

are free to move

through the

material

Insulator – electrons

tightly held, do

not move

16.3

16.3 Insulators and Conductors

Semiconductors – conduct electricity under some circumstances, don’t under other conditions

16.3

Electric Charge and Electric Field

16.4 Induced Charge; the Electroscope

16.4 Induced Charge; the Electroscope

Induction – charging without

contact

Object is brought near a

charged object

Electrons move

Object is grounded

An electroscope measures if

an object has a charge on

it16.4

Electric Charge and Electric Field

16.5 Coulomb’s Law

16.5 Coulomb’s Law

Electric charges apply forces to each other

From experiments

Force is proportional

to charge

Inversely proportional

to square of distance

16.5

1 22

q qF k

r

9 2 28.988 10 /k x Nm C

16.5 Coulomb’s Law

Equation – gives magnitude of force

Opposite charges – force directed toward

each other

Like charges – force directed away from each

other

Charge is measured in Coulombs

16.5

16.5 Coulomb’s Law

1 Coulomb is the amount of charge, that if placed 1 m apart would result in a force of 9x109 N

Charges are quantized – that is they come in discrete values

The constant k relates to the constant called the permittivity of free space

16.5

191.602 10e x C

12 2 20 8.85 10 /x C Nm

16.5 Coulomb’s Law

AP tends to write k as

We will assume that charges are point charges - size is negligible

16.5

0

1

4k

Electric Charge and Electric Field

16.6 Solving Problems Involving Coulomb’s Laws and Vectors

16.6 Coulomb’s Law and Vectors

Principle of Superposition – Electrostatic forces are added just like any other force

As vectors

16.6

Electric Charge and Electric Field

16.7 The Electric Field

16.7 The Electric Field

Electrical forces act over distances

Field forces, like gravity

Michael Faraday

electric field – extends

outward from every charge

and permeates all of space

The field is defined by the force

it applies to a test charge

placed in the field16.7

16.7 The Electric Field

The Electric field would then be

Or

q is the test charge

We can also say that

Remember that E is independent of the test charge.

The electric field is also a vector (free body diagrams are probably a good idea)

16.7

2r

kqE

q

FE

EqF

Electric Charge and Electric Field

16.8 Field Lines

16.8 Field Lines

To visualize electric fieldsDraw electric field linesDirection of the lines is the direction of force on a positive test chargeThe density of the lines indicates relative strength of the fieldNote: the field density increase as you get closer

16.8

16.8 Field Lines

For multiple charges, keep in mind

1. Field lines indicate the direction of the field

The actual field is tangent to the field lines

2. The magnitude of the field is relative to the field line density

3. Fields start at positive and end at negatives

16.8

Field Lines

16.8 Field Lines

If the field is produced by two closely spaced parallel plates

The field density is constant

So the electric field is

constant

16.8

Electric Charge and Electric Field

16.9 Electric Fields and Conductors

16.9 Electric Fields and Conductors

For a conductor

1. The electric field inside a

conductor is zero (static)

2. Any net charge is distributed on the surface of a conductor

3. Electric field is always

perpendicular to the surface of a conductor

2. Charges concentrate at the

area of greatest

curvature 16.9