Physics For Scientists And Engineers With Modern Physics, 9th Edition, The Ohio State University
Physics For Scientists And Engineers With Modern Physics, 9th Edition, The Ohio State University
9th Edition
ISBN: 9781305372337
Author: Raymond A. Serway | John W. Jewett
Publisher: Cengage Learning
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Question
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Chapter 8, Problem 82CP

(a)

To determine

The maximum height the ball attains when it swings up.

(a)

Expert Solution
Check Mark

Answer to Problem 82CP

The maximum height of the ball when it swings up is 1.61+8.64N2F2_.

Explanation of Solution

Consider the ball-string-wind as a system under gravitational force.

Since the work done by the wind on the system is transformed into potential energy of the system.

Write the equation for conservation of energy

  ΔU+ΔK=W                                                                                                (I)

Here, ΔU is the change in potential energy, ΔK is the change in kinetic energy and W is the work done by the force exerted by the wind.

Write the expression for the change in potential energy

  ΔU=UfUi                                                                                               (II)

Here, Uf is the final potential energy of the system and Ui is the initial potential energy of the system.

Since the kinetic energy of the systems remains zero because in both initial and final cases the system is not in rest.

Write the expression for potential energy

    U=mgh

Here, m is the mass of the system, g is the acceleration due to gravity and h is the height of the system from the ground.

.

Substitute mghf for Uf and mghi for Ui in equation (II).

    ΔU=(mghf)(mghi)=mg(hfhi)

Here, hf is the final height of the system from the ground and hi is the initial height of the system from the ground.

Since the difference in initial and final height is given by H.

    H=hfhi

Substitute hfhi for H in above expression as.

  ΔU=mgH

Substitute mgH for ΔU and 0 for ΔK in equation (I).

  mgH+0=W

Simplify the above equation.

  W=mgH

Write the expression for work done by the force

  W=Fd

Here, F is the force exerted by wind and d is the distance in the direction of force.

Substitute Fd for W in above equation.

  Fd=mgH                                                                                                 (III)

Physics For Scientists And Engineers With Modern Physics, 9th Edition, The Ohio State University, Chapter 8, Problem 82CP , additional homework tip  1

Write the expression for distance in the direction of the force exerted from the figure (I).

    d=L2(LH)2

Here, d is the horizontal distance traveled by the ball, L is the height of the string and H is the vertical distance traveled by the ball.

Simplify the above equation.

    d=2LHH2                                                                                         (IV)

Substitute 2LHH2 for d in equation (III).

    F2LHH2=mgH

Simplify the above equation.

    F2(2LHH2)=m2g2H22HF2LH2F2=m2g2H2(F2+m2g2)H22LF2H=0H((F2+m2g2)H2LF2)=0

Since one root of the above equation is zero, so take non-zero value of H.

Solve the above equation.

    H(F2+m2g2)2LF2=0H=2LF2F2+m2g2

Simplify the above equation to find the expression for H

    H=2L(11+(mgF)2)                                                                                   (V)

Conclusion:

Substitute 300g for m, 9.8m/s2 for g and 80.0cm for L in equation (V).

    H=2(80.0cm)(11+((300g)(9.8m/s2)F)2)=160.0(1m100cm)(11+((9.8m/s2)2(300(1kg1000g))2F2))=1.6m1+((96.04m2/s4)(0.09kg2)F2)

Simplify the above equation.

    H=1.61+8.64N2F2                                                                                        (VI)

Thus, the maximum height of the ball when it swings up is 1.61+8.64N2F2_.

(b)

To determine

The maximum height the ball attains when the force exerted by wind is 1N.

(b)

Expert Solution
Check Mark

Answer to Problem 82CP

The maximum height attained by the ball, when the force exerted by wind is 1N. is 0.166m_.

Explanation of Solution

Conclusion:

Substitute 1.00N for F in equation (V).

  H=1.6m1+8.64N2(1.00N)2=1.6m9.64=0.16597m0.166m

Thus, the maximum height attained by the ball, when the force exerted by wind is 1N is 0.166m_.

(c)

To determine

The maximum height the ball attains when the force exerted by wind is 10N.

(c)

Expert Solution
Check Mark

Answer to Problem 82CP

The maximum height attained by the ball, when the force exerted by wind is 10N. is 1.47m_.

Explanation of Solution

Consider the equation (V) for the maximum height attained due to the force exerted by the wind.

The ball swings in the upward direction by the wind force exerted on the ball.

Conclusion:

Substitute 10.0N for F in equation (VI).

  H=1.6m1+8.64N2(10.0N)2=1.6m1.0864=1.47275m1.47m

Thus, The maximum height attained by the ball, when the force exerted by wind is 10N. is 1.47m_.

(d)

To determine

The maximum height when the force exerted by wind approaches to zero.

(d)

Expert Solution
Check Mark

Answer to Problem 82CP

The maximum height approaches to zero when F approaches to zero.

Explanation of Solution

Write the expression for the maximum height in the limit form as.

    limF0H=limF0(1.6m1+8.64N2F2)=1.6m1+8.64N2limF0F2

Substitute 0 for limF0F2 in the above equation.

    H=1.6m1+8.64N20=1.6m1+=1.6mH=0

Conclusion:

Thus, the maximum height approaches to zero when F approaches to zero.

(e)

To determine

The behavior of maximum height when the force exerted by wind approaches to infinity.

(e)

Expert Solution
Check Mark

Answer to Problem 82CP

The maximum height approaches to 1.6m_ when F approaches to infinity.

Explanation of Solution

Write the expression for the maximum height in the limit form as.

    limFH=limF(1.6m1+8.64N2F2)=1.6m1+8.64N2limFF2

Substitute 0 for (limF8.64N2F2) in the above equation.

    H=1.6m1+0=1.6m

Thus, the maximum height approaches to 1.6m_ when F approaches to infinity.

(f)

To determine

The equivalent height of the ball with the wind blowing.

(f)

Expert Solution
Check Mark

Answer to Problem 82CP

The equivalent height of the ball with the wind blowing is (0.8m)(111+F28.64N2)_.

Explanation of Solution

Consider the system in an equilibrium state with net force zero as shown in figure (II).

Physics For Scientists And Engineers With Modern Physics, 9th Edition, The Ohio State University, Chapter 8, Problem 82CP , additional homework tip  2

Write the equation for net force in a vertical direction from the figure (II)

    Fy=Tcosθmg

Here, Fy is the net force in a positive y-axis direction. T is the force due to tension in the string, θ is the angle between the initial and final position of the ball-string as shown in the figure and m is the mass of the ball and g is the acceleration due to gravity.

When the ball-string system is in equilibrium, the net force will be zero in all directions.

  Faxis=0

Here, Faxis is algebric sum of required direction or axis.

Substitute 0 for Fy in above expression as.

    Tcosθmg=0

Simplify the above equation.

    cosθ=mgT                                                                                                (VII)

Write the equation for net force in a horizontal direction from the figure (II)

    Fx=FTsinθ

Here, Fx is the net force in the positive x-axis direction and F is the force exerted by the wind.

Substitute 0 for Fx in above expression as.

    FTsinθ=0

Simplify the above equation.

    sinθ=FT                                                                                                  (VIII)

Divide equaiton (VIII) by equation (VII).

  cosθsinθ=(mgT)(FT)tanθ=Fmg

Write the expression for cosθ in terms of tanθ

  cosθ=11+tan2θ

Substitute Fmg for tanθ in the above equation.

    cosθ=11+F2m2g2                                                                                    (IX)

Write the expression for equivalent height from the figure (II).

    heq=LLcosθ                                                                                           (X)

Here, heq is the equivalent height.

    mgF=1tanθ

Substitute 1tanθ for mgF in equation (VI).

    H=2L(11+(1tanθ)2)                                                                              (XI)

Conclusion:

Substitute 300g for m and 9.8m/s2 for g in equation (IX).

    cosθ=11+F2(300g)2(9.8m/s2)2=11+F2(300g)2(1kg1000g)2(9.8m/s2)2=11+F2(0.09kg2)(96.04m2/s4)=11+F28.64N2

Substitute 11+F28.64N2 for cosθ and 80cm for L in equation (X).

    heq=(80cm)(111+F28.64N2)=(80cm)(1m100cm)(111+F28.64N2)

Simplify the above expression as.

    heq=(0.8m)(111+F28.64N2)                                                              (XII)

Thus, the equivalent height of the ball with the wind blowing is (0.8m)(111+F28.64N2)_.

(g)

To determine

The equivalent height when 10N of force is exerted by the wind.

(g)

Expert Solution
Check Mark

Answer to Problem 82CP

The equivalent height when 10N of force is exerted by wind is 0.574m_.

Explanation of Solution

Conclusion:

Substitute 10N for F in equation (XII).

    heq=(0.8m)(111+(10N)28.64N2)=(0.8m)(111+11.57)=0.57460.574m

Thus, the equivalent height when 10N of force is exerted by wind is 0.574m_.

(h)

To determine

The equivalent height when the force exerted by wind approaches to infinity.

(h)

Expert Solution
Check Mark

Answer to Problem 82CP

The equivalent height when the force exerted by wind approaches to infinity is 0.8m_.

Explanation of Solution

Consider the equivalent height from the equation (XII).

Write the expression for equivalent height from the equation (XII).

    heq=0.8(111+F28.64)

Write the equation for limFheq from the above equation.

    limFheq=limF(0.8m)(111+F28.64N2)=(0.8m)(1limF11+F28.64N2)

Substitute 0 for (limF11+F28.64) in the above equation.

    limFheq=0.8 m(10)=0.8 m

Conclusion:

Thus, the equivalent height when the force exerted by wind approaches to infinity is 0.8m_.

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Chapter 8 Solutions

Physics For Scientists And Engineers With Modern Physics, 9th Edition, The Ohio State University

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