Magnetism A Magnetism the properties and interactions of

Magnetism A. Magnetism – the properties and interactions of magnets 1. 2. Interactions between two magnets called magnetic force increases as magnets move closer together. A magnetic field, which exerts the magnetic force, surrounds a magnet, and is strongest closest to the magnet.

Magnetism B. Magnetic poles – the regions of a magnet where the magnetic force exerted by the magnet is strongest 1. 2. 3. All magnets have a north pole and a south pole. Like poles attract. Unlike poles repel. Earth has magnetic poles. a. b. A compass needle is a small bar magnet that can freely rotate. A compass needle always points north.

Magnetism C. Magnetic materials – iron, cobalt, and nickel 1. 2. The magnetic field created by each atom exerts a force on nearby atoms. Magnetic domains – groups of atoms with aligned magnetic poles a. b. In a magnet, the like poles of all the domains point in the same direction. Permanent magnets are made by placing a magnetic material in a strong magnetic field forcing a large number of magnetic domains to line up.

Electricity

Section 1: Electric Charge A. Protons have positive electric charge; electrons have negative electric charge. 1. 2. 3. In most atoms, the charges of the protons and electrons cancel each other out and the atom has no net charge. Atoms become charged by gaining or losing electrons. Static electricity – the accumulation of excess electric charges on an object.

Section 1: Electric Charge B. Electrically charged objects obey the following rules: 1. 2. 3. 4. 5. Law of conservation of charge – charge may be transferred from object to object, but it cannot be created or destroyed. Opposite charges attract and like charges repel. Charges can act on each other even at a distance, because any charge that is placed in an electric field will be pushed or pulled by the field. Electrons move more easily through conductors, like metals. Electrons do not move easily through insulators such as plastic, wood, rubber, and glass.

Section 1: Electric Charge C. Transferring electric charge 1. Charging by contact a. b. 2. The process of transferring charge by touching or rubbing Ex: static electricity from your feet rubbing the carpet Charging by induction a. b. The rearrangement of electrons on a neutral object caused by a nearby charged object Ex: a negatively charged balloon near your sleeve causes an area of your sleeve to become positively charged

Section 1: Electric Charge 3. Static discharge a. b. A transfer of charge through the air between two objects because of a buildup of static electricity Ex: lightning Grounding – using a conductor to direct an electric charge into the ground. D. The presence of electric charges can be detected by an electroscope. 4.

Discussion Question #1 What do you think happens when you get static electricity in your hair? Answer: Some electrons from your hair move to the sweater or hairbrush, causing the sweater or hairbrush to have a negative charge, and your hair to have a positive charge. Your hair will attracted to the sweater or hairbrush. Strands of hair that are positively charged also might repel one another and lifts straight up in the air.

Section 2: Electric Current A. The flow of charges through a wire or conductor is called electric current. 1. 2. 3. Current is usually the flow of electrons. Electric current is measured in amperes (A). Charges flow from high voltage to low voltage. a. b. 4. A voltage difference is the push that causes charges to move. Voltage difference is measured in volts (V). For charges to flow, the wire must always be connected in a closed path, or circuit.

Section 2: Electric Current B. Sources of electricity: 1. 2. 3. A dry cell battery produces a voltage of difference between its zinc container and its carbon suspension rod, causing current to flow between them. A wet cell battery contains two connected plates made of different metals ina conducting solution. Wall sockets have a voltage difference across the two holes of an electrical outlet, and a generator at a power plant provides this voltage difference.

Section 2: Electric Current C. Resistance – the tendency for a material to oppose the flow of electrons, changing electrical energy into thermal energy and light. 1. 2. 3. D. All materials have some electrical resistance. Resistance is measured in ohms (W). Making wires thinner, longer, or hotter increases the resistance. Ohm’s law – the current in a circuit equals the voltage difference divided by the resistance.

Discussion Question #2 What property of electric current causes lightbulbs to give light? Answer: Resistance. As electrons flow through the filament, the filament resists flow and changes electrical energy into thermal energy and light.

Section 3: Electrical Circuits A. Circuits rely on generators at power plants to produce a voltage difference across the outlet, causing the charge to move when the circuit is complete. 1. Series circuit – the current has only one loop to flow through a. b. c. The parts of a series circuit are wired one after another, so the amount of current is the same through every part. Open circuit – if any part of the series circuit is disconnected, no current flows through the circuit Ex: strings of holiday lights

Section 3: Electrical Circuits 2. Parallel Circuit – contains two or more branches for current to move through a. b. Individual parts can be turned off without affecting the entire circuit. Ex: the electrical system in a house.

Section 3: Electrical Circuits B. Household circuits use parallel circuits connected in a logical network. 1. 2. 3. Each branch receives the standard voltage difference from the electric company. Electrical energy enters your home at the circuit breaker or fuse box and branches out to wall sockets, major appliances, and lights. Guards against overheating electric wires: a. b. Electric fuse – contains a small piece of metal that melts if the current becomes too high, opening the circuit and stopping the flow of current. Circuit breaker – contains a small piece of metal that bends when it gets hot, opening the circuit and stopping the flow of current.

Section 3: Electrical Circuits C. Electrical energy is easily converted to mechanical, thermal, or light energy. 1. Electrical power – the rate at which electrical energy is converted to another form of energy a. b. c. 2. Electrical power is expressed in watts (W). Power = current x voltage difference P (watts) = I (amperes) x V (volts) To calculate the amount of energy an appliance uses: a. b. c. The unit of electrical energy is the kilowatt-hour, which equals 1000 watts of power used for one hour. Energy = power x time E (k. Wh) = P (k. W) x t (h)

Discussion Question #3 Does your home have a fuse box or a circuit breaker? Why is it there? How does it work? Answer: It is there to make sure the electrical wires in our home do not get too hot and start fires. If the wires get too hot, they melt the piece of metal in the fuse or bend the piece of metal in the circuit. This opens the circuit and stops the flow of current. If we have a fuse box, we have to replace the melted fuse with a new one. If we have a circuit breaker, we only need to unplug some appliances and then flip the switch.