1. Electric Charge

2. Static Electricity
Static Electricity: a stationary electrical charge typically produced by friction
Works best on a dry day because excessive moisture can provide a pathway for charge to leak off a charged object.
Balloons
-attracted to hair and wall.
-repel each other

3. Electric Charge
Two Types of Electric Charge (distinguished by Benjamin Franklin)
Positive
Negative
Like Charges Repel & Unlike Charges Attract
Hair stands up because it has more negative charge and you hiar is repelling eachother.

4. The Atom Every Atom is made up of 3 Subatomic Particles
Protons (positively charged)
Neutrons (uncharged)
Electrons (negatively charged)

5. Ion Formation When # protons = # electrons, the atom has no net charge
Because electrons are outside the nucleus, they are easily transferred from one atom to another.
When one or more electrons are transferred the atoms are no longer neutron (ions)

6. Conservation of Electric Charge
Electric charge is not created or destroyed
Most objects are electrically neutral (positive and negative charges are balanced)
Friction makes these charges unbalanced.
Ballon gains electrons (-)
Hair loses electrons (+)
This build up of charge can be released through a circuit.

7. Electric Charge is Quantized
The SI unit of electric charge is the coulomb (C)
Electric charge is quantized. This means that charge occurs as integer multiples of e in nature. (e= 1.6 x 10^-19 C)
Particle
Charge (C)
Mass (kg)
Proton
+1.6 x 10^-19
1.67 x10^-27
Electron
-1.6 x 10^-19
9.11 x 10^-31
Neutron
1.67 x 10^-27

8. Materials
Materials are classified based on their ability to transfer electric charge
Conductors: materials in which electric charges can move freely
Ex: copper, aluminum, human body
Insulators: materials in which charges cannot move freely
Ex: glass, rubber, silk, plastic
Semiconductors: materials that share properties of both conductors and insulators
Ex: Silicon, Germanium
Superconductors: materials that have zero electrical resistance when at or below a certain temperature
The balloon is rubber, so it is an insulator. The charge from rubbing stays in only the part of the balloon that was rubbed.

9. Transfer of Electric Charge
**demos here**--transfer charge by touching
Electric Charge can be transferred from one object to another 3 ways:
Contact
Induction
Polarization

10. Transfer of Electric Charge by Contact
Conductors and Insulators can become charged by contact.

11. Transfer of Electric Charge by Induction
Step 1: a charged object is brought near (without touching) a neutral conductor.
Step 2: The presence of the charge object will force (or induce) electrons within the neutral conductor to move.
Step 3: Ground the conductor to discharge electrons
Step 4: Remove charged object and grounding wire. The conductor is left with a (+) charge.
Grounded-when a conductor is connected to Earth by a conducting wire
Earth is an infinite reservoir for electrons

12. Transfer of Electric Charge by Induction

13. Transfer of Electric Charge by Polarization
Polarization: the realignment of charge within individual molecules creating an induced charge on the surface of an insulator.
Both objects still have a net charge of zero
Ex: “Static Cling”

14. Electric Force
Field Force: a force that is exerted by one object on another even though there is no physical contact between the two objects. (Ex. Electric Force, Gravitational Force)
Two charged objects near one another may experience acceleration either toward or away from each other because each object exerts an Electric Force on the other object.
Qualitatively determined by the type of electric charge
Like charges repel
Unlike charges attract
What determines the quantitative value (magnitude) of this force?
Electric Field Force can be attractive or repulsive
Gravitational Force can only be attractive.

15. Coulomb’s Law
The magnitude of the Electric Force between objects is affected by…
The distance between the two objects
The amount of charge on the objects
F=Electric Force [N]
k= Coulomb’s Law Constant (k=9.0 x10^9 Nm^2/C^2)
q1=charge 1 [C]
q2=charge 2 [C]
r=distance [m]

16. Coulomb’s Law Practice #1
The electron and proton of a hydrogen atom are separated, on average, by a distance of about 5.3 x 10^-11 m. Find the magnitudes of the electric force and the gravitational force that each particle exerts on the other.

17. Coulomb’s Law Practice #2
Consider three point charges at the corners of a triangle, as shown, where q1=6x10^-9 C, q2=-2x10^-9 C, and q3=5x10^-9 C. Find the magnitude and direction of the resultant force on q3.

18. Coulomb’s Law Practice #3
When charged objects are said to be in equilibrium, the forces are equal in magnitude, but opposite in direction. Essentially the electric forces cancel each other out and the Net Electric Force is zero.
Three charges lie along the x-axis. One positive charge, q1=15 µC, is at x=2.0 m, and another positive charge, q2=6.0 µC, is at the origin. At what point on the x- axis must a negative charge, q3, be placed so that the resultant force on it is zero?