Learning Goal: A sled is being held at rest on a slope that makes an angle with the horizontal. After the sled is released, it slides a distance di down the slope and then covers the distance de along the horizontal terrain before stopping. Find the coefficient of kinetic friction between the sled and the ground, assuming that it is constant throughout the trip.

Transcribed Image Text:

Learning Goal: A sled is being held at rest on a slope that makes an angle with the horizontal. After the sled is released, it slides a distance d₁ down the slope and then covers the distance d₂ along the horizontal terrain before stopping. Find the coefficient of kinetic friction between the sled and the ground, assuming that it is constant throughout the trip. PROBLEM-SOLVING STRATEGY 10.1 Energy-conservation problems MODEL: Define the system so that there are no external forces or so that any external forces do no work on the system. If there's friction, bring both surfaces into the system. Model objects as particles and springs as ideal. VISUALIZE: Draw a before-and-after pictorial representation and an energy bar chart. A free-body diagram may be needed to visualize forces. SOLVE: If the system is both isolated and nondissipative, then the mechanical energy is conserved: Ki +U₁ = Kf +Uf. where K is the total kinetic energy of all moving objects and U is the total potential energy of all interactions within the system. If there's friction, then Ki + Ui = Kf + Uf + AEth. where the thermal energy increase due to friction is AEth = fk▲s. REVIEW: Check that your result has the correct units and significant figures, is reasonable, and answers the question. Model The problem involves friction. Therefore, all the objects involved in the dissipative interaction caused by friction should be included in the system. This means that for this problem, the system is composed of both the sled and the surface of the ground.

Transcribed Image Text:

In addition to a before-and-after pictorial representation, in energy problems it is often useful to draw energy bar charts, as the ones shown below. Taking the initial state of the system to be the moment when the sled is released from rest and the final state to be the moment when the sled comes to a stop, let K₁, U₁, Kf, and Uf be the sled's initial and final kinetic and gravitational energies, respectively; and AEth be the increase in thermal energy of the system. Take the gravitational energy of the sled at the bottom of the slope to be zero. Which of the following energy bar charts correctly describes the energy transformation occurring in this problem? O O O + 0+ T + O T K₁ + U₁ = K₁ + Uf + AEth Submit K₁ + U₁ = K₁ + Up + AEth + JJ + K₁ + U₁ = K₁ + Uf + AEth + K₁ + U₁ = K₁ + U₁ + AEth Request Answer