EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 8220100654428
Author: Jewett
Publisher: Cengage Learning US
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Textbook Question
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Chapter 36, Problem 36.46P

A diverging lens has a focal length of magnitude 20.0 cm. (a) Locate the image for object distances of (i) 40.0 cm, (ii) 20.0 cm, and (iii) 10.0 cm. For each case, state whether the image is (b) real or virtual and (c) upright or inverted.(d) For each case, find the magnification.

(a)

Expert Solution
Check Mark
To determine

The location of the image for given object distance.

Answer to Problem 36.46P

The location of the image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm are 13.3cm , 10.0cm and 6.67cm in front of the lens respectively.

Explanation of Solution

Given: The magnitude of the focal length of the lens is 20.0cm .

Write the equation for lens.

EBK PHYSICS FOR SCIENTISTS AND ENGINEER, Chapter 36, Problem 36.46P 1p+1q=1fq=pfpf (1)

Here,

p is the object distance.

q is the image distance.

f is the focal length of the lens.

The focal length is negative for diverging lens. The value of focal length is 20.0cm .

For case (i), the object distance is 40.0cm .

Substitute 40.0cm for p and 20.0cm for f in equation (1) to find q .

q=(40.0cm)(20.0cm)(40.0cm)(20.0cm)=13.3cm

Thus, the location of the image for an object distance of 40.0cm is 13.3cm in front of the lens.

For case (ii), the object distance is 20.0cm .

Substitute 20.0cm for p and 20.0cm for f in equation (1) to find q .

q=(20.0cm)(20.0cm)(20.0cm)(20.0cm)=10.0cm

Thus, the location of the image for an object distance of 20.0cm is 10.0cm in front of the lens.

For case (iii), the object distance is 10.0cm .

Substitute 10.0cm for p and 20.0cm for f in equation (1) to find q .

q=(10.0cm)(20.0cm)(10.0cm)(20.0cm)=6.67cm

The location of the image for an object distance of 10.0cm is 6.67cm in front of the lens.

Conclusion:

Therefore, the location of the image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm are 13.3cm , 10.0cm and 6.67cm in front of the lens respectively.

(b)

Expert Solution
Check Mark
To determine

Whether the image for the given object distance is real or virtual.

Answer to Problem 36.46P

The image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm is virtual for all the cases.

Explanation of Solution

Given: The magnitude of the focal length of the lens is 20.0cm .

The image is real when the image distance is positive (q>0) and the image is virtual when the image distance is negative (q<0) .

From the calculation of part (a) in case (i), the image distance is,

q=13.3cm

Thus, the image distance is 13.3cm which is negative due to which the image is virtual.

From the calculation of part (a) in case (ii), the image distance is,

q=10.0cm

Thus, the image distance is 10.0m which is negative due to which the image is virtual.

From the calculation of part (a) in case (iii), the image distance is,

q=6.67cm

The image distance is 6.67cm which is negative due to which the image is virtual.

Conclusion:

Therefore, the image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm is virtual for all the cases.

(c)

Expert Solution
Check Mark
To determine

Whether the image for the given object distance is upright or inverted.

Answer to Problem 36.46P

The image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm is upright for all the cases.

Explanation of Solution

Given: The magnitude of the focal length of the lens is 20.0cm .

Write the equation for magnification of the image.

M=qp (2)

Here,

M is the magnification of the image.

The image is upright when the magnification is positive (M>0) and the image is inverted when the magnification is negative (M<0) .

For case (i), the object distance is 40.0cm and the image distance is 13.3cm .

Substitute 13.3cm for q and 40.0cm for p in equation (2) to find M .

M=(13.3cm)(40.0cm)=0.333

The magnification is 0.333 which is positive due to which the image is upright.

For case (ii), the object distance is 20.0cm and the image distance is 10.0cm .

Substitute 10.0cm for q and 20.0cm for p in equation (2) to find M .

M=(10.0cm)(20.0cm)=0.500

The magnification is 0.500 which is positive due to which the image is upright.

For case (iii), the object distance is 10.0cm and the image distance is 6.67cm .

Substitute 6.67cm for q and 10.0cm for p in equation (2) to find M .

M=(6.67cm)(10.0cm)=0.667

The magnification is 0.667 which is positive due to which the image is upright.

Conclusion:

Therefore, the image for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm is upright for all the cases.

(d)

Expert Solution
Check Mark
To determine

The magnification for the given object distance.

Answer to Problem 36.46P

The magnification for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm are 0.333 , 0.500 and 0.667 respectively.

Explanation of Solution

Given: The magnitude of the focal length of the lens is 20.0cm .

From the calculation of part (c) in case (i), the magnification for an object distance of 40.0cm is,

M=0.333

Thus, the magnification is 0.333 .

From the calculation of part (c) in case (ii), the magnification for an object distance of 20.0cm is,

M=0.500

Thus, the magnification is 0.500 .

From the calculation of part (c) in case (iii), the magnification for an object distance of 10.0cm is,

M=0.667

The magnification is 0.667 .

Conclusion:

Therefore, the magnification for an object distance of (i) 40.0cm , (ii) 20.0cm , and (iii) 10.0cm are 0.333 , 0.500 and 0.667 respectively.

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Chapter 36 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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