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Which of these configurations gives V = 0 at all points on the y-axis? 4) all of the above 5) none of the above 10. Equipotential Surfaces III 1) x +2.

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Presentation on theme: "Which of these configurations gives V = 0 at all points on the y-axis? 4) all of the above 5) none of the above 10. Equipotential Surfaces III 1) x +2."— Presentation transcript:

1 Which of these configurations gives V = 0 at all points on the y-axis? 4) all of the above 5) none of the above 10. Equipotential Surfaces III 1) x +2  C -2  C +1  C -1  C 2) x +2  C -1  C +1  C -2  C 3) x +2  C -1  C -2  C +1  C

2 Which two points have the same potential? 1) A and C 2) B and E 3) B and D 4) C and E 5) no pair A C B D E Q 11. Equipotential of Point Charge

3 Which requires the most work, to move a positive charge from P to points 1, 2, 3 or 4 ? All points are the same distance from P. 1) P  1 2) P  2 3) P  3 4) P  4 5) all require the same amount of work P 1 2 3 4 12. Work and Electric Potential I

4 Which requires zero work, to move a positive charge from P to points 1, 2, 3 or 4 ? All points are the same distance from P. 1) P  1 2) P  2 3) P  3 4) P  4 5) all require the same amount of work P 1 2 3 4 13. Work and Electric Potential II

5 Capacitor C 1 is connected across a battery of 5 V. An identical capacitor C 2 is connected across a battery of 10 V. Which one has the most charge? C 1 1) C 1 C 2 2) C 2 3) both have the same charge 4) it depends on other factors +Q+Q –Q–Q 14. Capacitors

6 increase the area of the plates 1) increase the area of the plates decrease separation between the plates 2) decrease separation between the plates 3) decrease the area of the plates 4) either (1) or (2) 5) either (2) or (3) What must be done to a capacitor in order to increase the amount of charge it can hold (for a constant voltage)? +Q –Q 15. Varying Capacitance I

7 +Q+Q –Q–Q A parallel-plate capacitor initially has a voltage of 400 V and stays connected to the battery. If the plate spacing is now doubled, what happens? the voltage decreases 1) the voltage decreases the voltage increases 2) the voltage increases the charge decreases 3) the charge decreases the charge increases 4) the charge increases both voltage and charge change 5) both voltage and charge change 16. Varying Capacitance II

8 A parallel-plate capacitor initially has a potential difference of 400 V and is then disconnected from the charging battery. If the plate spacing is now doubled (without changing Q), what is the new value of the voltage? 100 V 1) 100 V 200 V 2) 200 V 3) 400 V 4) 800 V 5) 1600 V +Q+Q –Q–Q 17. Varying Capacitance III

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