100 200 300 400 500 Ch 32 Terms Ch 32 Main Ideas Ch 32 Charging Ch 33 Terms Ch 33 Main Ideas Ch 33 Van de Graff.

100 100 100 100 100 100

200 200 200 200 200 200

300 300 300 300 300 300

400 400 400 400 400 400

500 500 500 500 500 500

Ch 32 Terms Ch 32 Main Ideas

Ch 32 Charging

Ch 33 Terms Ch 33 Main Ideas

Ch 33 Van de Graff

Allows for the transmission of heat or electricity.

A 100

Conductor

A 100

The measurement of charge.

A 200

Coulomb

A 200

To draw off charges by touching it with our hand.

A 300

Grounding

A 300

Allows for infinite

conductivity.

A 400

Superconductor

A 400

Possesses the properties of a conductor and an insulator.

A 500

Semiconductor

A 500

Main analogy to electric fields.

B 100

Gravitational fields

B 100

Defines the reason that charges cannot be created nor

destroyed

B 200

Conservation of Charge

B 200

F=kq1q2/r2

B 300

Coulomb’s Law

B 300

The reason that superconductors are not in

wide-spread commercial use.

B 400

Must be at 4K

B 400

The larger force between gravity and electricity.

B 500

Electricity

B 500

The manner by which you charge yourself and get shocked by a doorknob.

C 100

Friction

C 100

The manner by which the confetti paper was charged before it flew off the rod.

C 200

Contact

C 200

The manner by which I can make your hair stand up

without touching it.

C 300

Induction

C 300

DAILY DOUBLE

C 400

DAILY DOUBLE

Place A Wager

The reason that no ones hair stood up with our Van de

Graff generator.

C 400

Too humid in the room

C 400

The reason that water can be deflected by a statically

charged balloon.

C 500

Charge polarization

C 500

Holds a charge in a field.

D 100

Capacitor

D 100

The space around an electric charge.

D 200

Electric field

D 200

The electric potential energy per charge

D 300

Electric potential

D 300

The energy a charge possesses due to its location.

D 400

Electric potential energy

D 400

The unit of electric potential.

D 500

Volt

D 500

The charge of a “test charge.”

E 100

Positive (always!)

E 100

A way to display the strength of a field with field lines.

E 200

Either with vector lengths or by the relative

proximity of the lines.

E 200

The reason you are safe in your car during an electrical

storm.

E 300

Electric shielding

E 300

Objects with mass have gravitational potential energy.

The comparison to charged particles is:

E 400

Electric potential energy

E 400

An electric train has signs that warn against 1,500 Volts, yet this is the charge on the

Van de Graff generator.

E 500

~150,000 Volts

E 500

The charge on the metal sphere.

F 100

Negative

F 100

The main reason that the aluminum pans flew off.

F 200

The top pan was repulsed by the lower pans, which were

all electrically negative.

F 200

The reason that we stood on a bucket.

F 300

To avoid grounding.

F 300

The reason that we stayed away from the gas jets,

radiators, and touching others

F 400

Grounding (or static discharge)

F 400

The reason that it is better to touch the metal rod with more of your hand/arm, rather than

just using your finger tip.

F 500

The charge is spread out and less concentrated.

F 500

The Final Jeopardy Category is:

Van de Graff

Please record your wager.

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When we were all in a circle, the first half of the circle received little or no shock, yet the last half received a much greater shock

than if they were alone. Explain.

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The charge built up on the circle was enough to fully charge 5-20 people (depending on the class),

so when the circuit was closed, 5-20 people worth of voltage was

delivered, rather than one persons charge.

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