Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 25: Electric Current and Direct Current Circuits

Published byKelley Oliver Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 25: Electric Current and Direct Current Circuits"— Presentation transcript:

1 Chapter 25: Electric Current and Direct Current Circuits

2 If 4.7 ´ 1016 electrons pass a particular point in a wire every second, what is the current in the wire? 4.7 mA 7.5 A 2.9 A 7.5 mA 0.29 A

3 If 4.7 ´ 1016 electrons pass a particular point in a wire every second, what is the current in the wire? 4.7 mA 7.5 A 2.9 A 7.5 mA 0.29 A

4 The graph shows the potential difference across a resistor as a function of the current through the resistor. The slope of the resulting curve represents power. resistance. emf. charge. work per unit charge.

5 The graph shows the potential difference across a resistor as a function of the current through the resistor. The slope of the resulting curve represents power. resistance. emf. charge. work per unit charge.

6 A resistor carries a current I
A resistor carries a current I. The power dissipated in the resistor is P. What is the power dissipated if the same resistor carries current 3I? P 3P P/3 9P P/9

7 A resistor carries a current I
A resistor carries a current I. The power dissipated in the resistor is P. What is the power dissipated if the same resistor carries current 3I? P 3P P/3 9P P/9

8 The power dissipated in each of two resistors is the same
The power dissipated in each of two resistors is the same. The potential drop across resistor A is twice that across resistor B. If the resistance of resistor B is R, what is the resistance of A? R 2R R/2 4R R/4

9 The power dissipated in each of two resistors is the same
The power dissipated in each of two resistors is the same. The potential drop across resistor A is twice that across resistor B. If the resistance of resistor B is R, what is the resistance of A? R 2R R/2 4R R/4

10 Two resistors are connected in series across a potential difference
Two resistors are connected in series across a potential difference. If the current carried by resistor A is I, what is the current carried by B? I 2I I/2 4I impossible to determine unless more is known about the resistances of A and B

11 Two resistors are connected in series across a potential difference
Two resistors are connected in series across a potential difference. If the current carried by resistor A is I, what is the current carried by B? I 2I I/2 4I impossible to determine unless more is known about the resistances of A and B

12 Four identical light bulbs are connected to a power supply as shown
Four identical light bulbs are connected to a power supply as shown. Which light bulb consumes the most power? B1 B2 B3 B4 They all consume the same amount of power.

13 Four identical light bulbs are connected to a power supply as shown
Four identical light bulbs are connected to a power supply as shown. Which light bulb consumes the most power? B1 B2 B3 B4 They all consume the same amount of power.

14 Four identical light bulbs are connected to a power supply as shown
Four identical light bulbs are connected to a power supply as shown. Which light bulb consumes the most power? B1 B2 B3 B4 They all consume the same amount of power.

15 Four identical light bulbs are connected to a power supply as shown
Four identical light bulbs are connected to a power supply as shown. Which light bulb consumes the most power? B1 B2 B3 B4 They all consume the same amount of power.

16 If two elements of a circuit are in parallel, they must have the same
charge. potential difference across them. resistance. potential difference across them and the same current. current.

17 If two elements of a circuit are in parallel, they must have the same
charge. potential difference across them. resistance. potential difference across them and the same current. current.

18 Which of the following relations among the quantities in the figure is generally correct?
I1R1 = I2R2 I3R3 = I4R4 I1R1 = I4R4 I3R4 = I4R3 I1R1 + I2R2 = e

19 Which of the following relations among the quantities in the figure is generally correct?
I1R1 = I2R2 I3R3 = I4R4 I1R1 = I4R4 I3R4 = I4R3 I1R1 + I2R2 = e

20 Three resistors are placed in a simple circuit
Three resistors are placed in a simple circuit. In which of the various configurations shown do all three resistors carry the same current?

21 Three resistors are placed in a simple circuit
Three resistors are placed in a simple circuit. In which of the various configurations shown do all three resistors carry the same current?

22 The power delivered by the battery in the circuit shown is

23 The power delivered by the battery in the circuit shown is

24 Capacitance

25 A capacitor of capacitance C holds a charge Q when the potential difference across the plates is V. If the charge Q on the plates is doubled to 2Q, the capacitance becomes (1/2)V. the capacitance becomes 2C. the potential changes to (1/2)V. the potential changes to 2V. the potential does not change.

26 A capacitor of capacitance C holds a charge Q when the potential difference across the plates is V. If the charge Q on the plates is doubled to 2Q, the capacitance becomes (1/2)V. the capacitance becomes 2C. the potential changes to (1/2)V. the potential changes to 2V. the potential does not change.

27 If a capacitor of capacitance 2. 0 µF is given a charge of 1
If a capacitor of capacitance 2.0 µF is given a charge of 1.0 mC, the potential difference across the capacitor is 0.50 kV. 2.0 V. 2.0 µV. 0.50 V. None of these is correct.

28 If a capacitor of capacitance 2. 0 µF is given a charge of 1
If a capacitor of capacitance 2.0 µF is given a charge of 1.0 mC, the potential difference across the capacitor is 0.50 kV. 2.0 V. 2.0 µV. 0.50 V. None of these is correct.

29 An 80-nF capacitor is charged to a potential of 500 V
An 80-nF capacitor is charged to a potential of 500 V. How much charge accumulates on each plate of the capacitor? 4.0 ´ 10–4 C 4.0 ´ 10–5 C 4.0 ´ 10–10 C 1.6 ´ 10–10 C 1.6 ´ 10–7 C

30 An 80-nF capacitor is charged to a potential of 500 V
An 80-nF capacitor is charged to a potential of 500 V. How much charge accumulates on each plate of the capacitor? 4.0 ´ 10–4 C 4.0 ´ 10–5 C 4.0 ´ 10–10 C 1.6 ´ 10–10 C 1.6 ´ 10–7 C

31 Doubling the potential difference across a capacitor
doubles its capacitance. halves its capacitance. quadruples the charge stored on the capacitor. halves the charge stored on the capacitor. does not change the capacitance of the capacitor.

32 Doubling the potential difference across a capacitor
doubles its capacitance. halves its capacitance. quadruples the charge stored on the capacitor. halves the charge stored on the capacitor. does not change the capacitance of the capacitor.

33 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in parallel. The charge on each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

34 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in parallel. The charge on each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

35 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in parallel. The voltage across each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

36 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in parallel. The voltage across each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

37 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in series. The charge on each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

38 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in series. The charge on each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

39 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in series. The voltage across each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

40 directly proportional to its capacitance.
Several different capacitors are hooked across a DC battery in series. The voltage across each capacitor is directly proportional to its capacitance. inversely proportional to its capacitance. independent of its capacitance.

Download ppt "Chapter 25: Electric Current and Direct Current Circuits"

Similar presentations

Q(M2): In a solenoid, if the number of turns increases by a factor of 2 and the length of the solenoid decreases by a factor of 2, what happens to the.

Q(M2): In a solenoid, if the number of turns increases by a factor of 2 and the length of the solenoid decreases by a factor of 2, what happens to the.
AP Electricity Quiz Review

AP Electricity Quiz Review
St Columba’s High School Electricity and Electronics Capacitors.

St Columba’s High School Electricity and Electronics Capacitors.
Q26.1 Which of the two arrangements shown has the smaller equivalent resistance between points a and b? A. the series arrangement B. the parallel arrangement.

Q26.1 Which of the two arrangements shown has the smaller equivalent resistance between points a and b? A. the series arrangement B. the parallel arrangement.
Which of the two cases shown has the smaller equivalent resistance between points a and b? Q26.1 1. Case #1 2. Case #2 3. the equivalent resistance is.

Which of the two cases shown has the smaller equivalent resistance between points a and b? Q Case #1 2. Case #2 3. the equivalent resistance is.
© 2012 Pearson Education, Inc. Demographics A. Electrical Engineering B. Other Engineering C. Physics D. Chemistry E. Other.

© 2012 Pearson Education, Inc. Demographics A. Electrical Engineering B. Other Engineering C. Physics D. Chemistry E. Other.
© 2012 Pearson Education, Inc. Which of the two arrangements shown has the smaller equivalent resistance between points a and b? Q26.1 A. the series arrangement.

© 2012 Pearson Education, Inc. Which of the two arrangements shown has the smaller equivalent resistance between points a and b? Q26.1 A. the series arrangement.
Concept Questions with Answers 8.02 W10D2

Concept Questions with Answers 8.02 W10D2
©1997 by Eric Mazur Published by Pearson Prentice Hall Upper Saddle River, NJ 07458 ISBN 0-13-565441-6 No portion of the file may be distributed, transmitted.

©1997 by Eric Mazur Published by Pearson Prentice Hall Upper Saddle River, NJ ISBN No portion of the file may be distributed, transmitted.
Chapter 23 Circuits.

Chapter 23 Circuits.
Electric Circuits Review Chapter 17 & 18 Electrical resistance in a wire depends on the wire’s 1.Resistivity 2.Length 3.Cross sectional area 4.All of.

Electric Circuits Review Chapter 17 & 18 Electrical resistance in a wire depends on the wire’s 1.Resistivity 2.Length 3.Cross sectional area 4.All of.
Physics Review #1 LCHS Dr.E. A positive test charge is placed between an electron, e, and a proton, p, as shown in the diagram below. When the test charge.

Physics Review #1 LCHS Dr.E. A positive test charge is placed between an electron, e, and a proton, p, as shown in the diagram below. When the test charge.
Capacitors and/or TV (not Emf). 1. An empty capacitor does not resist the flow of current, and thus acts like a wire. 2. A capacitor that is full of charge.

Capacitors and/or TV (not Emf). 1. An empty capacitor does not resist the flow of current, and thus acts like a wire. 2. A capacitor that is full of charge.
Let us now use this realistic view of a battery in a simple circuit containing a battery and a single resistor. The electric potential difference across.

Let us now use this realistic view of a battery in a simple circuit containing a battery and a single resistor. The electric potential difference across.
Section 24-1: Capacitance

Section 24-1: Capacitance
Physics of Everyday Phenomena

Physics of Everyday Phenomena
Cutnell/Johnson Physics 8th edition

Cutnell/Johnson Physics 8th edition
(Capacitance and capacitors)

(Capacitance and capacitors)
Chapter 23 Circuits Topics: Sample question:

Chapter 23 Circuits Topics: Sample question:
DC circuits Physics Department, New York City College of Technology.

DC circuits Physics Department, New York City College of Technology.

Similar presentations

Ads by Google