(a) Explanation Refer to Figure P8.62. When the spring has been compressed by a distance d it comes to rest. Therefore final velocity of the system is zero so final kinetic energy is also zero. Before compression the spring was in its natural state so initial elastic potential energy is also zero. Write the expression for work done by the spring on the block. Δ U s = 1 2 k x i 2 − 1 2 k x f 2 (I) Here, x i is initial stretch of the spring, k is force constant, x f is final stretch of the spring and Δ U s is change in elastic potential energy of the system. Write the expression for change in kinetic energy of the system. Δ K = 1 2 m v f 2 − 1 2 m v i 2 (II) Here, Δ K is change in kinetic energy, m is mass, v i is initial velocity and v f is final velocity. Write the expression for the normal reaction force experience by the block. n = m g Here, n is the normal reaction force and g is acceleration due to gravity. Write the expression for friction force. f k = μ k n (III) Here, f k is frictional force, μ k is coefficient of friction. Substitute m g for n in equation (III). f k = μ k m g Here, d is the distance by which the object moves when the spring is compressed. The total internal energy stored in the system is due to frictional force experienced by the block in moving the distance ( d ) . Write the expression for total internal energy. Δ E int = f k d Here, Δ E int total internal energy stored in the system. Substitute μ k m g for f k above equation. Δ E int = μ k m g d As energy of the system is conserved, therefore change in elastic potential energy by the spring is equal to change in kinetic energy and total internal energy due to friction force. Write the expression for conservation of energy for the system. Δ U s = Δ K + Δ E int (IV) Substitute 1 2 m v f 2 − 1 2 m v i 2 for Δ K , ( μ k m g d ) for Δ E int and 1 2 k x i 2 − 1 2 k x f 2 for Δ U s in equation (IV) (b) To determine The speed at the unstretched position when the object is moving to the left. (c) To determine The distance D where the object comes to rest.

Physics for Scientists and Engineers with Modern Physics, Technology Update

9th Edition

ISBN: 9781305401969

Author: SERWAY, Raymond A.; Jewett, John W.

Publisher: Cengage Learning

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Chapter 8, Problem 62AP

(a)

To determine

The distance of compression d.

(b)

To determine

The speed at the unstretched position when the object is moving to the left.

(c)

To determine

The distance D where the object comes to rest.

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Chapter 8, Problem 61AP

Chapter 8, Problem 63AP

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A 1.30 kg object slides to the right on a surface having a coefficient of kinetic friction 0.250 (Fig. P7.54). The object has a speed of vi = 2.60 m/s when it makes contact with a light spring that has a force constant of 50.0 N/m. The object comes to rest after the spring has been compressed a distance d. The object is then forced toward the left by the spring and continues to move in that direction beyond the spring's unstretched position. The object finally comes to rest a distance D to the left of the unstretched spring. Figure P7.54 (a) Find the distance of compression d. m(b) Find the speed v at the unstretched position when the object is moving to the left. m/s(c) Find the distance D where the object comes to rest. m

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A block of mass m=5.5kg slides on a rough surface and moves toward a spring with a spring constant k=1022N/m, as shown in the figure below. When the block is d=27.4m away from the spring, it has a velocity of v=14.8m/s. When the block momentarily stops, it has compressed the spring by x=16cm. What is the coefficient of kinetic friction between the block and the surface below? Provide your answer with two decimal places. Take g=9.80m/s2.

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Physics for Scientists and Engineers with Modern Physics, Technology Update

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The distance of compression d .

Solution Summary: The author explains the distance of compression, the kinetic energy, and the expression for the normal reaction force experience by the block.

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The distance of compression d.

The speed at the unstretched position when the object is moving to the left.

The distance D where the object comes to rest.

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Chapter 8 Solutions