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S8P5. Students will recognize characteristics of gravity, electricity, and magnetism as major kinds of forces acting in nature. b. Demonstrate the advantages and disadvantages of series and parallel circuits and how they transfer energy. c. Investigate and explain that electric currents and magnets can exert force on each other.
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Direct Current- charges always flow in the same direction Alternating Current- charges continually shift from flowing in one direction to flowing in the reverse direction
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1.Circuit 2.Electrical Current 3.Voltage 4.Resistance
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Rate at which electrical charges (electrons) pass a given point measured in amperes or amps (A)
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A measure of how much work is needed to move a charge (current) between two points. Potential difference between two points in a circuit measured in volts (v)
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opposition to the amount of current in a wire OR “electric friction” measured in ohms(Ω)
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Cell or Battery - device produces electric current by converting chemical or radiant energy into electrical energy Thermocouple - device produces electric current by converting thermal energy into electrical energy Photocells - device produces electric current by converting light energy into electrical energy
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AC current is produced by a generator, usually at a power plant. Power plants convert moving water, fossil fuels, nuclear power, wind, solar energy into electrical energy
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Why are some substances magnetic and other substances are not?
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A magnet is an object that is surrounded by a magnetic field and that has the property of attracting iron.
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The spinning electrons in every atom produce tiny magnetic fields. In most materials the fields of atoms point in random directions so the magnetic fields cancel each other out.
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In some materials the magnetic fields of electrons align with one another. A cluster of atoms with magnetic fields lined up in the same way is known as a magnetic domain.
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For an object to be magnetic, most of its domains (tiny magnetic fields produced by spinning electrons) must be aligned in the same direction.
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A pole is the area of a magnetic where the magnetic effect is the strongest. Every magnetic has two poles – often called the north and south pole.
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Magnets can produce: –An attractive force (pulling) when unlike magnetic poles attract –A repulsive force (pushing) when like magnetic poles repel. Sounds a lot like the Law of Charges!
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Magnetic force is caused by a magnet attracting (pulling) other magnets and some other materials (e.g. iron and steel)
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Magnetic force is also caused by a magnet repelling (pushing) other magnets and some other materials (e.g. iron and steel)
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A magnetic field is area around the magnet in which magnetic forces act; concentrated into a pattern of lines that extend from the magnet’s north pole to its south pole.
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Magnetic energy results when an object is moved a distance by a magnetic force. Two Kinds of magnets: a) Temporary - easy to magnetize and demagnetize easily b) Permanent - hard to magnetize or demagnetize
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What is the difference between a motor and a generator?
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A compass points to the Earth’s North Pole because the Earth acts like a giant magnet. (The core of the Earth is mostly molten iron.)
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Earth has a north magnetic pole and a south magnetic pole.
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Earth’s magnetic poles are not exactly the same locations as the geographic poles (axis where the Earth spins).
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A compass can be used to find directions because its needle lines up with the Earth’s magnetic poles.
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What would happen to the magnetic properties of a bar magnetic if you cut it into two pieces?
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Losing Magnetic Alignment by: – a) Dropping a magnet or hitting it too hard – b) Putting magnet in opposite field for too long – c) Increasing the temperature How can a magnet lose its magnetic properties?
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An electromagnet is a coil of current- carrying wire that acts as a magnet that can be turned on and off.
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Solenoid = a current-carrying coil of wire with many loops. When a solenoid is turned on, a magnetic field is created.
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If a piece of iron or other ferromagnetic material is wrapped by the coils of wire in a solenoid, a magnet is created when the current is turned on.
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The strength of an electromagnet can be increased by: – 1)Increasing the electric current in the solenoid – 2)Increasing the number of coil loops around the ferromagnetic material – 3)Using a stronger ferromagnetic material (more iron content)
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Examples of Electromagnet Uses: a)A doorbell or an alarm b)Moving junk cars c)Recording data on your computer d)Reading the magnetic strip on the back of a credit card
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a) A doorbell or an alarm
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b) Moving junk cars
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d) Reading the magnetic strip on the back of a credit card
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Electromagnetism - interaction between electricity and magnetism - Magnetic forces arise from the movement of electrical charge. - Electrical forces arise from the movement of a magnet (induced current) Big Idea about Electricity and Magnetism
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An electric motor is a device that changes electrical energy into mechanical energy. All electric motors have an armature—a loop or coil of wire that can rotate. The armature is mounted between the poles of a permanent magnet or electromagnet. Motors
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A generator is a device that uses electromagnetic induction to change mechanical energy into electrical energy. An electric current is made when a magnet moves in a coil of wire or when a wire moves between the poles of a magnet (electromagnetic induction). Generators
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