Units of Chapter 19

• Electric Charge

• Insulators and Conductors

• Coulomb's Law

• The Electric Field

• Electric Field Lines

• Shielding and Charging by Induction

• Electric Flux and Gauss's Law

Electric Charge

Nature and Properties of Electric Charge

Electric charge is a fundamental property of matter, arising from its atomic structure. Atoms consist of a positively charged nucleus surrounded by negatively charged electrons. Most matter is electrically neutral, but electrons are mobile and can be separated from atoms with relative ease.

• Definition: Electric charge is a physical property that causes matter to experience a force when placed in an electromagnetic field.

• Types of Charge: There are two types: positive (protons) and negative (electrons).

• Magnitude of Charge: All electrons have the same charge, C; protons have C.

• Unit: The SI unit of charge is the coulomb (C).

• Charge Conservation: The total electric charge of the universe is constant; charge is conserved in all processes.

• Quantization: Electric charge exists in discrete units, multiples of .

• Ions: Atoms that lose electrons become positive ions; those that gain electrons become negative ions.

Example: The total charge of 1.0 kg of electrons is C.

Charging by Friction and Polarization

• Materials can be charged by friction when unlike materials are rubbed together (e.g., amber rod and fur).

• Static electricity is the result of charge transfer by friction.

• Some materials can become polarized, meaning their atoms rotate in response to an external charge, allowing a charged object to attract a neutral one.

Insulators and Conductors

Classification of Materials

Materials are classified based on their ability to allow electrons to move:

• Conductors: Materials (usually metals) whose conduction electrons are free to move throughout. Excess charge resides on the surface.

• Insulators: Materials (usually nonmetals) whose electrons seldom move from atom to atom.

• Semiconductors: Materials with properties intermediate between conductors and insulators; their conductivity depends on chemical composition.

• Photoconductors: Materials that become conductive when exposed to light.

Coulomb's Law

Force Between Point Charges

Coulomb's law describes the force between two point charges:

• Formula:

• Constant:

• Direction: The force is attractive if charges are opposite, repulsive if they are alike.

• Action-Reaction: Forces on the two charges are equal in magnitude and opposite in direction.

• Superposition Principle: For multiple charges, the net force is the vector sum of individual forces.

• Spherical Distributions: Coulomb's law applies to spherically symmetric charge distributions, analogous to gravitational forces.

Example: For three charges on the x-axis, the net force on is calculated by summing the forces from the other two charges using Coulomb's law and vector addition.

Result: N, below –x.

The Electric Field

Definition and Properties

The electric field is a vector field that represents the force per unit charge at a point in space.

• Definition: , where is a test charge.

• Unit: Newton per coulomb (N/C).

• Force on a Charge:

• Direction: For positive charges, force is in the direction of the field; for negative charges, opposite.

• Point Charge Field: The field points radially away from positive charges and toward negative charges.

• Superposition: Electric fields from multiple sources add as vectors.

Example: The electric field at 20 cm from a C charge is N/C, +x direction.

Electric Field Lines

Visualization and Rules

Electric field lines are a graphical representation of the electric field's direction and strength.

• Field lines point in the direction of the field vector at every point.

• They start at positive charges (or infinity) and end at negative charges (or infinity).

• Field lines are denser where the field is stronger.

• The number of lines is proportional to the magnitude of the charge.

• Combinations of charges produce complex field patterns; the field is not necessarily zero where there are no lines.

• Parallel-plate capacitors have uniform field lines between plates.

Shielding and Charging by Induction

Behavior of Conductors and Induction

Conductors exhibit unique behaviors in electric fields due to the mobility of their electrons.

• Excess charge on a conductor resides on its surface, as charges move to maximize separation.

• When charges are at rest, the electric field inside a conductor is zero.

• The electric field is always perpendicular to the surface of a conductor.

• The field is stronger where the surface is more sharply curved.

• Charging by induction involves grounding a conductor to allow like charges to leave; isolating the conductor before removing the external charge leaves only the excess charge.

Summary Table: Key Concepts of Chapter 19

Additional info:

• These notes expand on the provided slides with full academic context, definitions, and examples for clarity and completeness.