Physics for Scientists and Engineers with Modern, Revised Hybrid (with Enhanced WebAssign Printed Access Card for Physics, Multi-Term Courses)
Physics for Scientists and Engineers with Modern, Revised Hybrid (with Enhanced WebAssign Printed Access Card for Physics, Multi-Term Courses)
9th Edition
ISBN: 9781305266292
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 26, Problem 34P

(a)

To determine

The equivalent capacitance of the system.

(a)

Expert Solution
Check Mark

Answer to Problem 34P

The equivalent capacitance of the system is 12.0μF .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

The capacitors C1andC2 are in series.

Formula to calculate the equivalent capacitance of the system when they are connected in series.

1Ceq=1C1+1C2 (1)

Here,

Ceq is the equivalent capacitance of the system when they are connected in series.

C1 is the value of capacitor 1.

C2 is the value of capacitor 2.

Substitute 18.0μF for C1 , 36.0μF for C2 in equation (1) to find Ceq ,

1Ceq=118.0μF+136.0μFCeq=12.0μF

Thus, the equivalent capacitance of the system is 12.0μF .

Conclusion:

Therefore, the equivalent capacitance of the system is 12.0μF .

(b)

To determine

The energy stored in this equivalent capacitance.

(b)

Expert Solution
Check Mark

Answer to Problem 34P

The energy stored in this equivalent capacitance is 864μJ .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

Formula to calculate the energy stored in this equivalent capacitance.

E=12CV2 (2)

Here,

E is the energy stored in this equivalent capacitance.

V is the voltage of the battery.

C is the capacitance of the system.

Substitute 12.0V for V , 12.0μF for C in equation (2) to find E ,

E=12(12.0μF)×(12.0V)2=864μJ

Thus, the energy stored in this equivalent capacitance is 864μJ .

Conclusion:

Therefore, the energy stored in this equivalent capacitance is 864μJ .

(c)

To determine

The energy stored in each individual capacitor.

(c)

Expert Solution
Check Mark

Answer to Problem 34P

The energy stored in the capacitor 1 is 576μJ , energy stored in the capacitor 2 is 288μJ .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

In series connection, the charge will be same in capactor 1 and capacitor 2,

Q1=Q2C1V1=C2V2 (3)

It is given that the total voltage of the battery is 12.0V .

Write the expression to calculate the voltage across capacitor 1.

V1+V2=12.0VV1=12.0VV2 (4)

Substitute 12.0VV2 for V1 in equation (3) to find V2 ,

V2=C1C2(12.0VV2) (5)

Substitute 18.0μF for C1 , 36.0μF for C2 in equation (5) to find V2 ,

V2=18.0μF36.0μF(12.0VV2)=60.5V21.5V2=6V2=4.0V

Thus, the voltage across capacitor 2 is 4.0V .

Substitute 4.0V for V in equation (4) to find V1 ,

V1=12.0V4.0V=8.0V

Thus, the voltage across capacitor 1 is 8.0V .

Formula to calculate the energy stored in the capacitor 1.

E1=12C1V2 (6)

Here,

E1 is the energy stored in the capacitor 1.

Substitute 12.0V for V , 18.0μF for C in equation (6) to find E1 ,

E1=12(18.0μF)×(8.0V)2=576μJ

Thus, the energy stored in the capacitor 1 is 576μJ .

Formula to calculate the energy stored in the capacitor 2.

E2=12C2V2 (7)

Here,

E2 is the energy stored in the capacitor 2.

Substitute 12.0V for V , 36.0μF for C in equation (7) to find E2 ,

E2=12(36.0μF)×(4.0V)2=288μJ

Thus, the energy stored in the capacitor 2 is 288μJ .

Conclusion:

Therefore, the energy stored in the capacitor 1 is 576μJ , energy stored in the capacitor 2 is 288μJ .

(d)

To determine

To show: The sum of these two energies is the same as the energy found in part (b).

(d)

Expert Solution
Check Mark

Answer to Problem 34P

The sum of these two energies is the same as the energy found in part (b) is 864μJ .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

The energy stored in this equivalent capacitance is 864μJ .

The energy stored in the capacitor 1 is 576μJ .

The energy stored in the capacitor 2 is 288μJ .

Formula to calculate the sum of these two energies.

E=E1+E2 (8)

Here,

E is the sum of these two energies.

Substitute 576μJ for E1 , 288μJ for E2 in equation (8) to find E ,

E=576μJ+288μJ=864μJ

Thus, the sum of these two energies is the same as the energy found in part (b).

Conclusion:

Therefore, the sum of these two energies is the same as the energy found in part (b) is 864μJ .

(e)

To determine

The reason that this equality will always be true, or the reason that it depends on the number of capacitors and their capacitances.

(e)

Expert Solution
Check Mark

Answer to Problem 34P

This equality will always be true because the energy stored in series and parallel for the capacitors is same.

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

Formula to calculate the energy stored by the capacitor in series.

ES=E1+E2

Here,

ES is the energy stored by the capacitor in series.

Formula to calculate the energy stored by the capacitor in parallel.

EP=E1+E2

Here,

EP is the energy stored by the capacitor in parallel.

The value of the energy stored by the capacitor in series and the energy stored by the capacitor in parallel are equal so, this equality will always be true.

Thus, this equality will always be true because the energy stored in series and parallel for the capacitors is same.

Conclusion:

Therefore, this equality will always be true because the energy stored in series and parallel for the capacitors is same.

(f)

To determine

The required potential difference across them so that the combination stores the same energy as in part (b).

(f)

Expert Solution
Check Mark

Answer to Problem 34P

The required potential difference across them so that the combination stores the same energy as in part (b) is 5.656V .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

If the same capacitors are connected in parallel.

Formula to calculate the equivalent capacitance of the system when they are connected in parallel.

Ceq=C1+C2 (9)

Here,

Ceq is the equivalent capacitance of the system when they are connected in parallel.

The energy stored in this equivalent capacitance is 864μJ .

Formula to calculate the required potential difference across them so that the combination stores the same energy as in part (b).

E=12CeqV2V=2ECeq (10)

Substitute 864μJ for E , C1+C2 for Ceq in equation (10) to find V ,

V=2×864μJC1+C2 (11)

Substitute 18.0μF for C1 , 36.0μF for C2 in equation (11) to find V ,

V=2×864μJ18.0μF+36.0μF=5.656V

Thus, the required potential difference across them so that the combination stores the same energy as in part (b) is 5.656V .

Conclusion:

Therefore, the required potential difference across them so that the combination stores the same energy as in part (b) is 5.656V .

(g)

To determine

The capacitor stores more energy C1orC2 .

(g)

Expert Solution
Check Mark

Answer to Problem 34P

The capacitor C1 stores more energy because the energy store by the capacitor 1 i.e, C1 is more than the energy stored by the capacitor 2 i.e, C2 .

Explanation of Solution

Given information: The value of capacitor 1 is 18.0μF , value of capacitor 2 is 36.0μF , voltage of the battery is 12.0V .

The capacitor C1 stores more energy because the energy store by the capacitor 1 i.e, C1 is more than the energy stored by the capacitor 2 i.e, C2 .

Thus, the capacitor C1 stores more energy.

Conclusion:

Therefore, the capacitor C1 stores more energy because the energy store by the capacitor 1 i.e, C1 is more than the energy stored by the capacitor 2 i.e, C2 .

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Chapter 26 Solutions

Physics for Scientists and Engineers with Modern, Revised Hybrid (with Enhanced WebAssign Printed Access Card for Physics, Multi-Term Courses)

Ch. 26 - Prob. 6OQCh. 26 - Prob. 7OQCh. 26 - Prob. 8OQCh. 26 - Prob. 9OQCh. 26 - Prob. 10OQCh. 26 - Prob. 11OQCh. 26 - Prob. 12OQCh. 26 - Prob. 13OQCh. 26 - Prob. 14OQCh. 26 - Prob. 1CQCh. 26 - Prob. 2CQCh. 26 - Prob. 3CQCh. 26 - Explain why a dielectric increases the maximum...Ch. 26 - Prob. 5CQCh. 26 - Prob. 6CQCh. 26 - Prob. 7CQCh. 26 - Prob. 8CQCh. 26 - (a) When a battery is connected to the plates of a...Ch. 26 - Two conductors having net charges of +10.0 C and...Ch. 26 - Prob. 3PCh. 26 - An air-filled parallel-plate capacitor has plates...Ch. 26 - Prob. 5PCh. 26 - Prob. 6PCh. 26 - When a potential difference of 150 V is applied to...Ch. 26 - Prob. 8PCh. 26 - Prob. 9PCh. 26 - Prob. 10PCh. 26 - Prob. 11PCh. 26 - Review. A small object of mass m carries a charge...Ch. 26 - Prob. 13PCh. 26 - Prob. 14PCh. 26 - Find the equivalent capacitance of a 4.20-F...Ch. 26 - Given a 2.50-F capacitor, a 6.25-F capacitor, and...Ch. 26 - Prob. 17PCh. 26 - Prob. 18PCh. 26 - Prob. 19PCh. 26 - Prob. 20PCh. 26 - A group of identical capacitors is connected first...Ch. 26 - Prob. 22PCh. 26 - Four capacitors are connected as shown in Figure...Ch. 26 - Prob. 24PCh. 26 - Prob. 25PCh. 26 - Prob. 26PCh. 26 - Two capacitors give an equivalent capacitance of...Ch. 26 - Prob. 28PCh. 26 - Prob. 29PCh. 26 - Prob. 30PCh. 26 - Prob. 31PCh. 26 - A 3.00-F capacitor is connected to a 12.0-V...Ch. 26 - Prob. 33PCh. 26 - Prob. 34PCh. 26 - Prob. 35PCh. 26 - Two identical parallel-plate capacitors, each with...Ch. 26 - Two capacitors, C1 = 25.0 F and C2 = 5.00 F, are...Ch. 26 - A parallel-plate capacitor has a charge Q and...Ch. 26 - Prob. 39PCh. 26 - Prob. 40PCh. 26 - Prob. 41PCh. 26 - Prob. 42PCh. 26 - Prob. 43PCh. 26 - Prob. 44PCh. 26 - Determine (a) the capacitance and (b) the maximum...Ch. 26 - Prob. 46PCh. 26 - Prob. 47PCh. 26 - Prob. 48PCh. 26 - Prob. 49PCh. 26 - Prob. 50PCh. 26 - An infinite line of positive charge lies along the...Ch. 26 - Prob. 52PCh. 26 - Prob. 53PCh. 26 - Prob. 54APCh. 26 - Prob. 55APCh. 26 - Prob. 56APCh. 26 - A uniform electric field E = 3 000 V/m exists...Ch. 26 - Prob. 58APCh. 26 - Prob. 59APCh. 26 - Why is the following situation impossible? A...Ch. 26 - Prob. 61APCh. 26 - A parallel-plate capacitor with vacuum between its...Ch. 26 - Prob. 63APCh. 26 - Prob. 64APCh. 26 - Prob. 65APCh. 26 - (a) Two spheres have radii a and b, and their...Ch. 26 - Prob. 67APCh. 26 - A parallel-plate capacitor of plate separation d...Ch. 26 - Prob. 69APCh. 26 - Prob. 70APCh. 26 - To repair a power supply for a stereo amplifier,...Ch. 26 - Prob. 72CPCh. 26 - Prob. 73CPCh. 26 - Consider two long, parallel, and oppositely...Ch. 26 - Prob. 75CPCh. 26 - Prob. 76CPCh. 26 - Prob. 77CPCh. 26 - Prob. 78CP
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