Recommended for: Grades 3-8
Resource: Exploring Conductivity: Kid Circuits
Media Type:
QuickTime Video
Length: 3m 32s
Size: 5.0 MB
In this video segment adapted from ZOOM, cast members become electron conductors to reconnect a broken electric circuit. By joining hands, the cast members complete, or close, a circuit that had been broken when the lemon powering a digital clock was sliced in half. Power is restored as soon as electrons are again allowed to flow uninterrupted from the lemon battery to the clock.
Supplemental Media Available:
Exploring Conductivity: Kid Circuits (HTML Document)
Teachers' Domain, Exploring Conductivity: Kid Circuits, published January 29, 2004, retrieved on ,
http://www.teachersdomain.org/resource/phy03.sci.phys.mfe.zcircuit/
- Background Essay
- Questions for Discussion
- Standards
In the 21st century, billions of people rely on electrical energy in one form or another. Today, even in some of the most remote regions, electricity powers lights, radios, televisions, and many other devices that help people to be more productive, comfortable, and informed.
In some places, electricity is generated by hydroelectric dams or coal-fired power plants. In others it comes from self-contained units called "dry cells, " also known as batteries. Regardless of its source, the resulting electric current is the same -- it is the flow of electrons through a substance.
In order for electric current to flow, three conditions must be met. One is presence of a substance that allows electrons to move, or flow, easily through it. Such substances, called conductors, are made up of atoms that hold their electrons loosely, allowing them to flow freely to other nearby atoms.
The second requirement is the presence of a power source. Whatever its form, a source of electric current creates what is called a voltage difference, which pushes electrons through the circuit. The chemical reactions inside batteries produce voltage differences between one end of the cell and the other that result in electric current.
Lastly, electric current requires a closed circuit, a length of conducting material connected at each end to a power source that also passes through the "load," the object that makes use of the current. A closed circuit allows a direct, uninterrupted flow of electrons out from the power source and back again in a complete circular connection with no beginning or end.
As demonstrated in the video segment from ZOOM, kids can act as conductors of electric current, though compared with some other substances, they're not very good ones! How do we know this? The reading on the voltmeter, which measures the voltage difference, decreases as more and more cast members join hands. Now, if lengths of copper wire were connected to each other in place of the chain of kids, there would be little or no such decrease. This is because copper wire, like most metals, is a good conductor.
In some places, electricity is generated by hydroelectric dams or coal-fired power plants. In others it comes from self-contained units called "dry cells, " also known as batteries. Regardless of its source, the resulting electric current is the same -- it is the flow of electrons through a substance.
In order for electric current to flow, three conditions must be met. One is presence of a substance that allows electrons to move, or flow, easily through it. Such substances, called conductors, are made up of atoms that hold their electrons loosely, allowing them to flow freely to other nearby atoms.
The second requirement is the presence of a power source. Whatever its form, a source of electric current creates what is called a voltage difference, which pushes electrons through the circuit. The chemical reactions inside batteries produce voltage differences between one end of the cell and the other that result in electric current.
Lastly, electric current requires a closed circuit, a length of conducting material connected at each end to a power source that also passes through the "load," the object that makes use of the current. A closed circuit allows a direct, uninterrupted flow of electrons out from the power source and back again in a complete circular connection with no beginning or end.
As demonstrated in the video segment from ZOOM, kids can act as conductors of electric current, though compared with some other substances, they're not very good ones! How do we know this? The reading on the voltmeter, which measures the voltage difference, decreases as more and more cast members join hands. Now, if lengths of copper wire were connected to each other in place of the chain of kids, there would be little or no such decrease. This is because copper wire, like most metals, is a good conductor.
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Source: ZOOM
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