Physics for Scientists and Engineers with Modern Physics
Physics for Scientists and Engineers with Modern Physics
10th Edition
ISBN: 9781337553292
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 7, Problem 45AP

(a)

To determine

The expression for the two forces in unit vector notation.

(a)

Expert Solution
Check Mark

Answer to Problem 45AP

The expression for the first force in unit vector notation is (20.5i^+14.3j^)N and the expression for the second force in unit vector notation is (36.4i^+21.0j^)N .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the expression for the first force in unit vector notation is

F1=(F1cosθ1)i^+(F1sinθ1)j^

  • F1 is the unit vector notation of the first force.
  • F1 is the magnitude of the first force.
  • θ1 is the angle made by the first force from the horizontal.

Substitute 25.0N for F1 and 35.0° for θ1 in above expression.

F1=((25.0N)cos35.0°)i^+((25.0N)sin35.0°)j^=(20.5i^+14.3j^)N

Conclusion:

Therefore, the expression for the first force in unit vector notation is (20.5i^+14.3j^)N .

(b)

To determine

The total force exerted on the object.

(b)

Expert Solution
Check Mark

Answer to Problem 45AP

The total force exerted on the object is (15.9i^+35.3j^)N .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the total force exerted on the object is,

F=F1+F2

  • F is the total force exerted on the object.

Substitute (20.5i^+14.3j^)N for F1 and (36.4i^+21.0j^)N for F2 .

F=(20.5i^+14.3j^)N+(36.4i^+21.0j^)N=(15.9i^+35.3j^)N

Conclusion:

Therefore, the total force exerted on the object is (15.9i^+35.3j^)N .

(c)

To determine

The acceleration on the object.

(c)

Expert Solution
Check Mark

Answer to Problem 45AP

The acceleration on the object is (3.18i^+7.06j^)N .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the acceleration of the object is,

F=ma

  • a is the acceleration of the object.

Substitute (15.9i^+35.3j^)N for F and 5.00kg for m to find a .

(15.9i^+35.3j^)N=(5.00kg)aa=15.00kg(15.9i^+35.3j^)N=(3.18i^+7.06j^)N

Conclusion:

Therefore, the acceleration on the object is (3.18i^+7.06j^)N .

(d)

To determine

The velocity on the object.

(d)

Expert Solution
Check Mark

Answer to Problem 45AP

The velocity on the object is (5.54i^+23.7j^)m/s .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the velocity of the object at t=3.00s is,

vf=vi+at

  • vf is the velocity vector of the object at t=3.00s .
  • vi is the velocity vector of the object at origin.
  • t is the time interval during the motion of the object.

Substitute (4.00i^+2.50j^)m/s for vi , (3.18i^+7.06j^)N for a and 3.00s for t to find vf .

vf=(4.00i^+2.50j^)m/s+[(3.18i^+7.06j^)N](3.00s)=(4.00i^+2.50j^)m/s+(9.54i^+21.18j^)m/s=(5.54i^+23.7j^)m/s

Conclusion:

Therefore, the velocity on the object is (5.54i^+23.7j^)m/s .

(e)

To determine

The position on the object.

(e)

Expert Solution
Check Mark

Answer to Problem 45AP

The position on the object is (2.3i^+39.3j^)m .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the position of the object is,

r=vit+12at2

  • r is the position vector of the object at t=3.00s .

Substitute (4.00i^+2.50j^)m/s for vi , (3.18i^+7.06j^)N for a and 3.00s for t to find r .

r=[(4.00i^+2.50j^)m/s](3.00s)+12[(3.18i^+7.06j^)N](3.00s)2=(12.0i^+7.50j^)m/s+(14.31i^+31.77j^)m/s=(2.3i^+39.3j^)m/s

Conclusion:

Therefore, the position on the object is (2.3i^+39.3j^)m .

(f)

To determine

The kinetic energy of the object from the formula 12mvf2 .

(f)

Expert Solution
Check Mark

Answer to Problem 45AP

The kinetic energy of the object from the formula 12mvf2 is

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the magnitude of the final velocity of the object is,

vf=vfx2+vfy2

  • vf is the magnitude of the final velocity of the object.

Substitute 5.54m/s for vfx and 23.7m/s for vfy to find vf .

vf=(5.54m/s)2+(23.7m/s)2=24.34m/s

(g)

To determine

The kinetic energy of the object from the formula 12mvi2+FΔr .

(g)

Expert Solution
Check Mark

Answer to Problem 45AP

The kinetic energy of the object from the formula 12mvi2+FΔr is 1.48kJ .

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

Formula to calculate the magnitude of the initial velocity of the object is,

vi=vix2+viy2

  • vi is the magnitude of the final velocity of the object.

Substitute 4.00m/s for vix and 2.50m/s for viy to find vi .

vi=(4.00m/s)2+(2.50m/s)2=4.72m/s

(h)

To determine

The conclusion by comparing the answer of part (f) and (g).

Introduction: Newton gave the law for the constant acceleration motion while the work energy theorem relates the work done by the object to its energy.

(h)

Expert Solution
Check Mark

Explanation of Solution

Given Information:

The mass of an object is 5.00kg , the magnitude of the first force is 25.0N at an angle of 35.0° and the magnitude of the second force is 42.0N at an angle of 150° . The velocity of the object at origin is vi=(4.00i^+2.50j^)m/s .

In part (f) the kinetic energy of the object is calculated with the help of Newton’s law while the kinetic energy in part (g) is calculated by the work energy theorem. Since in both the parts the kinetic energy of the object comes out to be same that conclude both the law and theorem are relevant to each other. The work energy theorem is consistent with the Newton’s law.

Conclusion:

Therefore, the work energy theorem is consistent with the Newton law’s of equation.

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Chapter 7 Solutions

Physics for Scientists and Engineers with Modern Physics

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